DE29723859U1 - C02 sensor device, in particular CO2 warning device - Google Patents

Description

Utility model application for CO2 sensor device, in particular CO2 warning device

The invention relates to a CO2 sensor device, in particular a CO2 warning device, with a radiation source (10) in front of a reflector mirror (49), by which the radiation is bundled and guided through a measuring tube (13) through which the gaseous sample flows to at least one infrared sensor (35, 37) and wherein a reference channel and a measuring channel are provided for the radiation, each of which is formed by filters (38, 39) with different spectral transmission ranges and wherein the radiation may experience a specific radiation absorption in the measuring channel, but not in the reference channel, which is detected by at least one infrared sensor (35, 37) and with an associated electronic computer and evaluation circuit, in which a determination of the CO2 content of the sample and its display takes place.

European Patent Application 0 555 508 A1 relates to a method and a device for the simultaneous determination of the concentrations of molecular compounds in gases and liquids.

In Fig. 4 and Fig. 5 of this EP-OS, a method is described in which a measuring tube on the one hand is irradiated by a radiation source via a parabolic mirror and on the other hand the radiation is evaluated by a sensor.

Very complex mechanical filters are arranged in the beam path between the radiation source and the measuring tube. These are movable by motors, are susceptible to failure and at the same time take up a lot of space.

Furthermore, these are essentially purely schematic representations from which the expert cannot derive any information regarding the practical design of the device.

The object of the invention is to increase the measurement accuracy and the consistency of the measurement results and to simplify and reduce the cost of the device.

The invention solves the problem in that the CO2 sensor device has a carrier plate (1) from which at least two column-like profile parts (3) extend vertically, each of which has a side profile (5) running radially to a common vertical (4) of the carrier plate (1) at the same distance from the vertical, such that the radius (6) of these side profiles (5) corresponds to a radius of a cylindrical measuring cartridge (12) formed from the infrared light source (10), its holder (11) and the measuring tube (13), which is inserted in the holder (14) formed by the radii (6) of the profile parts (3).

One embodiment of this invention is that the measuring cartridge is inserted into the fixation (14) of the carrier plate (1) on the stop (16, 51).

Another development of the invention is recognized in that the stop (16, 51) between the measuring cartridge (12) and the fixing (14) is formed by a shoulder (51) of the former (12) running transversely to the vertical (4) and a shoulder (16) of the profile parts (3).

Other inventive developments of the subject matter of the application can be found in the following description and the claims.

Show it:

Fig. 1: A front view in section of a CO2 sensor device according to

Line I-I according to Fig. 3.

Fig. 2: A front view in section of another CO2 sensor

device according to line H-II in Fig. 3.

Fig.3: A top view of a single part of the CO2 sensor device.

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From Figures 1 and 2 of the drawings, which are sectional views along the line I-I and the line H-II, which is a top view of the carrier plate 1 alone in Figure 3, it can be seen that columnar profile parts 3 extend vertically upwards on the carrier plate 1, which are designed as hollow parts (7) formed together with the carrier plate. The carrier plate 1 is advantageously manufactured as a metal injection molded part, in particular from aluminum injection molding.

Advantageously, three column-like profile parts 3 are formed on the carrier plate 1, since this allows a favorable guidance of the measuring cartridge 12 in the fixation 14 formed by the three column-like profile parts 3.

The profile parts 3 have a uniform distance from a common vertical 4 to the carrier plate 1, which is formed by a common radius of the side profiles 5 of the profile parts 3. The described design of the carrier plate 1 and the design of its moldings 3 are part of the invention.

As can be seen from Figures 1 and 2, the measuring cartridge 12 consists of the measuring tube 13 and the radiator attachment 42 attached to the top of the latter, which in turn is formed from the attachment bushing 43 and an attachment tube molded onto the latter. This measuring cartridge 12 is then received with the outer radius (51) of its measuring tube 13 in the holder or fixation 14 formed by three profile parts 3 of the carrier plate 1. The radius (51) of the measuring tube 13 corresponds to the radius 6 formed by the side profiles 5 of the profile parts opposite the vertical 4.

The measuring tube 13 of the measuring cartridge 12 abuts with its lower end on a surface 52 on the carrier plate 1, whereby the vertical position of the measuring cartridge 12 relative to the carrier plate 1 is determined. This design and mounting of the measuring cartridge 12 is also part of the invention.

The measuring tube 13 is, on the other hand, attached to the attachment tube 44 of the attachment bushing 43 by means of the attachment 51, which is provided in a ring shape on the

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Stop 16 is fixed, which is formed by recesses provided at the top of the profile parts 3. By flanging or mortising the attachment of the measuring cartridge 12 or the attachment bushing 43, the former (12) is firmly fixed in its holder or receptacle (fixing) 14.

From Fig. 1 it can be seen that the measuring cartridge 12 carries the radiator attachment 42 at the top, whose attachment bushing 43 has the lamp holder 46 with the radiation source 10 designed as a light bulb 45 at its end facing away from the measuring tube 13, and that the attachment bushing 43 has the optical reflector 49 formed or molded into the attachment tube 44 on the inside at its end facing the measuring tube 13. The lamp holder 46 itself is designed as a sleeve in which the light bulb 45 is held with its electrical connections.

In this case, the design is such that the lamp holder 46 with the inserted bulb 45 is designed to be adjustable in the direction of the axis 4 of the measuring cartridge 12 and around this axis 4 for the optimal optical positioning of its light focus and can be fixed by means of a screw 47 provided in the attachment bushing 43. In this way, the light focus can be adapted to the inserted bulb 45, which serves as the radiation source 10.

These above-explained details of the measuring tube 13 and its emitter attachment 42, and thus the measuring cartridge 12, are also part of the invention.

Within the scope of these further developments, which are considered inventive, it is also provided that the lamp holder 46 is designed as a sleeve which, together with the inserted bulb 45, penetrates the attachment bushing 43 in an inner bore and the bulb 45 projects into the area of the reflector 49 in the interior of the attachment tube 44.

According to the invention, the carrier plate 1 has a trough-like formation 20 on the side 19 facing away from the column-like profile parts 3 with the measuring cartridge 12, in which a printed circuit board 21 with the electronic components 22 of the CO2 sensor circuit is arranged. This trough-like formation 20 is advantageously covered at the bottom of the carrier plate 1 by a base plate 24.

According to the invention, this base plate 24 is firmly connected to the carrier plate 1 and has on its side 31 facing away from the carrier plate 1 suitable formations 32 and locking elements 32 for fastening the measuring device according to the invention on a DIN rail or the like.

According to the invention, an arrangement is made such that an infrared sensor unit 35 is arranged on the printed circuit board 21, specifically on the side of the same (21) facing the measuring cartridge 12, and that an opening 36 is provided in the area of the infrared sensor unit 35 in the carrier plate 1. The infrared sensor unit 35 is arranged with its optical center lying in the vertical 4 of the mount 14 of the carrier plate 1. The infrared sensor unit 35 advantageously has two sensor elements 37, with the optical reference filter 38 being assigned to one sensor element 37 and the optical measuring filter 39 being assigned to the other sensor element 37 in the beam path.

According to the invention, the two sensor elements 37 of the infrared sensor unit 35 are arranged adjacent to one another and the respective associated filters 38, 39 are arranged directly in front of these (37) in the optical beam path. For this purpose, the two sensor elements 37 together with the optical filters 38, 39 arranged in front of them are expediently combined in a common holder 40 with their electrical connections to the infrared sensor unit 35. For this purpose, the arrangement of the two sensor elements 37 together with their filters 38, 39 is advantageously housed in a standard housing, in particular a so-called TO housing. According to the invention, the structure can be such that the sensor elements 37 and their respective associated filters 38, 39 are constructed in a sandwich-like manner, housed next to one another in the housing. The measuring cartridge 12 and the infrared sensor unit 35 together form the measuring system of the CO2 gas sensor device.

According to the invention, the arrangement of the measuring cartridge 12 in the holder 14 in the carrier plate 1 is covered by a protective hood 25 which is completely or partially open at the bottom, near the carrier plate 1, for the passage of air 26.

It is expedient to provide pillars 28 at the bottom of the protective hood opening 26, on the edge of which, with which the protective hood 25 can be fastened to the support plate 1, by means of the pillars 28 at a distance from the latter (1).

Advantageously, the protective hood 25 is surrounded at the bottom in the area of its openings for the air inlet by a splash-proof cover 30, which is formed by molding the carrier plate 1 at its edge.

According to another development of the arrangement according to the invention, slots 56 are provided on the side of the wall of the measuring tube 13, through which better ventilation of the gas sphere of the measuring tube 13 is made possible. According to another development of the invention, elongated, radially extending wing-like parts 54 are provided within the protective cover 25, which serve to guide and calm the flow. These can be provided both on the carrier plate 1 and on the protective cover 25. It is also possible to arrange them on the measuring tube 13, projecting radially from it.

The vertical arrangement of the measuring cartridge 12 on the carrier plate 1 ensures that the lamp holder 46 and thus the bulb 45 can be easily replaced. Furthermore, the lamp holder 46 can be easily moved in the vertical direction 4 by means of a screw connection 47 in the spotlight attachment 42, and thus the bulb 45 can be adjusted.

The way the measuring cartridge 12 is mounted on the carrier plate 1 ensures good ventilation, even when the protective cover 25 is in place.

The base plate 24, which is connected to the carrier plate 1, also enables vertical installation, which means that the device can be used universally, e.g. on a DIN rail.

The trough-like formation 20 between the carrier part and the base plate 24 protects the circuit board 21. The sensor unit 35 on the one hand and other components 22 on the other hand and the circuit board 21 represent an assembly unit.

The base plate 24 is attached to the carrier plate 1. Screws are provided for this purpose and are inserted into screw holes.

Fig. 1 shows an embodiment with the internal details. There you can see the spotlight attachment 42 with the lamp holder 46 and the bulb 45 and with the attachment tube 44. Furthermore, the measuring tube 13 and the sensors 35, 37 are shown on the printed circuit board 21.

List of reference symbols

CO2 sensor device, in particular CO2 warning device.

No. Designation Addition / Remark 1 Carrier plate 2 3 (columnar) profile parts v. 1 4 vertical v. 1, 12, 13 5 Side profile v. 1,3 6 radius v. 5, 3 7 Hollow profiles v. 3 8th 9 10 Infrared light source 11 bracket v. 10 12 Measuring cartridge 13 Measuring tube v. 12 14 Version v. 12 (formed by 3,5,6) 15 16 attack v. 14 17 18 19 Side facing away from the measuring cartridge 12 of 1 20 Tub-like formation v. 1, 19 21 Printed circuit board 22 Electronic components v. 21 23 Sheet No.: 1 Number of sheets: 3

List of reference symbols

CO2 sensor device, in particular CO2 warning device.

No. Designation Addition / Remark 24 Base plate v. 1,19,20,21 25 Protective cover v. 1, 3, 12 26 Opening for air passage v. 25 27 drilling v. 1 28 pier v. 25, 26 29 30 cover v. 1, 25, 26 31 Side facing away from carrier plate 1 v. 24 32 Formations, locking elements Showing 31 of 24 33 34 All-round bridge v. 1 35 IR sensor unit v. 21 36 opening v. 1 for 12 37 Sensor element v. 35 38 Reference filter v. 35,37 39 Measuring filter v. 35, 37 40 bracket v. 35 41 42 Spotlight attachment v. 12, 13 43 Attachment socket v. 42 44 Attachment pipe v. 42, 43 45 light bulb v. 42, 43, 46 46 Lamp holder v. 42, 43 Sheet No.: 2 Number of sheets: 3

List of reference symbols

CO2 sensor device, in particular CO2 warning device.

No. Designation Addition / Remark 47 Adjusting screw v. 43, 46 48 Inner bore v. 43 49 reflector v. 43,45 50 51 Approach v. 44, 42 52 surface v. 1, 13 53 54 Wing part v. 25, 1 55 56 Slots v. 13 Sheet No.: 3 Number of sheets: 3

Claims (19)

- 1 claims 1.) CO2 sensor device, in particular CO2 warning device, with a radiation source (10) in front of a reflector mirror (49), through which the radiation is bundled and guided through a measuring tube (13) through which the gaseous sample flows to at least one infrared sensor (35, 37), and wherein a reference channel and a measuring channel are provided for the radiation, which are each formed by filters (38, 39) with different spectral transmission ranges, and wherein the radiation may experience a specific radiation absorption in the measuring channel, but not in the reference channel, which is detected by at least one infrared sensor (35, 37), and with an associated electronic computer and evaluation circuit, in which the CO2 content of the sample is determined and displayed, characterized in that that the measuring cartridge (12) consists of the measuring tube (13) with the emitter attachment (42) attached at the top. 2.) CO2 sensor device according to claim 1,
characterized, that the radiator attachment (42) is formed from the attachment bushing (43) and an attachment tube (44) molded onto it. 3.) CO2 sensor device according to claim 1 or 2,
characterized, that the attachment bushing (43) has the lamp holder (46) with the radiation source (10) at its end facing away from the measuring tube (13). 4.) CO2 sensor device according to claim 3,
characterized,
that the radiation source (10) is designed as an incandescent lamp (45). 5.) CO2 sensor device according to claim 3,
characterized, that the attachment bushing (43) has an optical reflector (49) formed or shaped inside the attachment tube (44) at its end facing the measuring tube (13). 6.) CO2 sensor device according to claim 4, characterized in that the lamp holder (46) is designed as a sleeve in which the light bulb (45) is held. 7.) CO2 sensor device according to one or more of claims 3, 4 or 6, characterized in that the lamp holder (46) with the inserted bulb (45) is designed to be adjustable in the direction of the axis (4) of the measuring cartridge (12). 8.) CO2 sensor device according to claim 7, characterized in that the lamp holder (46) with the inserted bulb (45) is adjustable about this axis (4) of the measuring cartridge (12) itself. 9.) CO2 sensor device according to claim 7 or 8, characterized in that the lamp holder (46) with the inserted bulb (45) can be fixed by means of a screw (47) provided in the attachment socket (43). 10.)CO2 sensor device according to claim 4, characterized in that the lamp holder (46) designed as a sleeve, together with the inserted bulb (45), penetrates the attachment bushing (43) in an inner bore (48) and the bulb (45) projects into the area of the reflector (49) in the interior of the attachment tube (44). l.)CO2 sensor device according to claim 1, characterized in that the carrier plate (1) with the column-like profile parts (3) has a trough-like formation (20) on the side (19) facing away from the measuring cartridge (12), in which a printed circuit board (21) with the electronic components (22) of the CO2 sensor circuit is arranged. 12.)CO2 sensor device according to claim 11, characterized in that the trough-like formation (20) at the bottom of the carrier plate (1) is covered by a base plate (24). 13.)CO2 sensor device according to claim 1 or 11, characterized in that an infrared sensor unit (35) is arranged on a printed circuit board (21), specifically on the side of the board (21) facing the measuring cartridge (12). 14.)CO2 sensor device according to claim 13, characterized in that an opening (36) is provided in the carrier plate (1) in the vicinity of the IR sensor unit (35). 15.)CO2 sensor device according to claim 14, characterized in that the IR sensor unit (35) is arranged with its optical center lying in the vertical (4) of the frame 14 of the carrier plate (1). 16.)CO2 sensor device according to one or more claims 13 - 15, characterized in that the IR sensor unit (35) has two sensor elements (37), whereby the one sensor element (37) is assigned the optical reference filter (38) and the other sensor element (37) is assigned the optical measuring filter (39) in the beam path. 17.)CO2 sensor device according to claim 16, characterized in that the two sensor elements (37) of the IR sensor unit (25) are arranged adjacent to one another and the respective associated filters (38, 39) are arranged immediately in front of these (37) in the optical beam path. 18.)CO2 sensor device according to claim 17,
characterized, that the sensor elements (37) and their respective associated filters (38, 39) are constructed in a sandwich-like manner and housed next to one another in the housing. 19.)CO2 sensor device according to claim 17 or 18,
characterized, that the two sensor elements (37) together with the optical filters (38, 39) arranged in front of them are structurally housed in a common holder (40) with their electrical connections to the IR sensor unit (3) together with their filters TO housing.