DE102021109431A1 - Combustion chamber sensor and method of installation - Google Patents

Abstract

The invention relates to a method for installing a sensor (5) in a combustion chamber (2), the sensor (5) being provided with a protective sleeve (9) that can be shrunk or burned off under the action of heat in a measuring area (6) protruding into the combustion chamber (2). installed at its destination and then a combustion is carried out in the combustion chamber (2), in which the protective cover (9) burns essentially without residue or shrinks to the extent that the sensor is essentially exposed. The invention also relates to a sensor (5) for a combustion chamber (2), the sensor (5) having a protective sleeve ( 9) which can burn essentially without residue or can shrink to such an extent that the sensor (5) is essentially exposed. The present invention brings about comprehensive transport and installation protection for a sensor 5 for a combustion chamber 2 and allows error-free installation even under unfavorable space conditions when constructing a heating device.

Description

The invention relates to a sensor, in particular a temperature sensor, for installation in a combustion chamber and a method for installing it and putting it into operation. Combustion chambers, especially of heaters, are often equipped with sensors, for example to measure the temperature at specific points. Instrumentation of this kind makes sense, especially for heating devices for operation with hydrogen, which will be in greater demand in the future. It is not only a question of large systems, but also of wall-mounted units for heating water and, in general, heaters for heating buildings and/or providing hot water. Other types of sensors are also commonly used in combustion chambers. Such sensors typically have a part containing the actual sensor, which is fastened in a holder, in particular a base, foot or flange, through which electrical leads are also routed. The bracket is attached to a wall in such a way that the actual sensor protrudes into a combustion chamber and the supply lines are accessible and can be connected on the other side of the wall.

In some sensors, particularly temperature sensors with low heat capacity, the actual sensor is long (e.g. 5 to 15 cm [centimeters]) and thin (cross-sectional area of e.g. 0.5 to 25 mm ² [square millimeters]) and can therefore easily bent or otherwise damaged during transport or installation if handled improperly. Particularly in the combustion chambers of heaters, sensors are preferably arranged on a burner door (or burner flap) next to a burner and must then be inserted through an opening into the combustion chamber together with the burner and other built-in components when the door is installed. But there are similar problems elsewhere.

It is known to provide sensitive components with a protective cover during transport or installation, which is then generally only removed when the last access to the component occurs during assembly. However, this does not change the fact that the final assembly steps often have to be carried out without a protective cover, as has been the case up to now, e.g. This is also the case, for example, when installing sensors in a burner door.

The object of the present invention is to at least partially solve the problems described with reference to the prior art. In particular, a method for the safe installation of a sensor in a combustion chamber and a sensor that is suitable for carrying out this method are to be created.

A method and a sensor or a protective cover according to the independent claims are used to solve this problem. Advantageous refinements and developments of the invention are specified in the respective dependent claims. The description, in particular in connection with the drawing, illustrates the invention and specifies further exemplary embodiments.

A method for installing a sensor in a combustion chamber contributes to this, in which the sensor is installed at its destination in a measuring area protruding into the combustion chamber and is provided with a protective sleeve that can be shrunk and/or burned off under the action of heat, and combustion is then carried out in the combustion chamber in which the protective cover substantially (residue-free) burns up or shrinks to the extent that the sensor is substantially exposed.

While in known methods at some point a protective cover z. B. has to be removed manually and the further installation has to be completed without a protective cover, which involves a certain risk of damage to the sensor, the method described here does not have this risk. The protective cover simply remains on the sensor and burns up and/or shrinks during the first (trial) start-up of the combustion chamber. The fact that the protective cover burns essentially "residue-free" means that no disturbing residues should remain on the sensor and/or in the combustion chamber, i.e. the combustion products of the protective cover can be almost completely removed from the combustion chamber with normal exhaust gases. However, small residues in the combustion chamber or on a sensor holder would not cause any problems. In the case of a (at least partially) shrinkable material, the shrinkage should accordingly be so great that the sensor is essentially exposed and ready for use after the first heat effect. However, a shrunken remainder of the protective cover can be located in the area of a holder.

The sensor is preferably a temperature sensor which is built into a wall, door or flap of a housing of a combustion chamber of a heating device.

The object is also achieved by a sensor for a combustion chamber, the sensor having a protective cover that can be shrunk and/or burned off under the action of heat in a measuring area that can be inserted into the combustion chamber when it is installed, which (essentially backwards free standing) or shrink to the extent that the sensor is essentially exposed. In this way, the actual sensor is protected during transport and installation and is not exposed to any risk from removing the protective cover, since it can be shrunk or burned off and does not have to be removed manually.

The sensor can have a holder for attachment to a wall, door or flap of a housing of a combustion chamber. Such a design corresponds to commercially available sensors for the purposes described.

The protective cover is preferably supported on the holder and the measuring area that can be introduced into the combustion chamber lies entirely within the protective cover. In this case, the protective cover does not have to be designed to be manually removable, for example by means of a sliding fit or a thread on the holder. It is even an advantage if it is not designed to be easily detachable manually, since then incorrect assembly without a protective cover is not possible. This also results in simplifications in production when attaching the protective cover, because it can be attached so that it cannot be lost.

The protective cover unfolds its particular advantages with sensitive and/or easily bendable sensors in which the measuring area that can be introduced into the combustion chamber has a length of 1 to 15 cm [centimeters] and without the protective cover a cross-section of 0.5 to 25 mm ² [square millimeters]. . Temperature sensors are often long and thin, because on the one hand they should protrude far into a combustion chamber, but on the other hand they have to react quickly, which is why they shouldn't have a large heat capacity of their own. This requires a very slim design, which usually leads to round cross-sections with diameters of z. B. 0.5 to 3 mm [millimeters].

The protective cover is preferably made of plastic and/or cardboard. The material costs are low and many plastics as well as cardboard can be easily shaped and, if necessary, burned with practically no residue. Instead of burning, the desired function can also be achieved by shrinking the protective cover through the action of heat. It is possible that the protective cover comprises several parts or materials, so that the desired burning and/or shrinking can be adjusted.

In particular, since the protective cover does not have to be removable, it can be cast or molded around the sensor, allowing for quick and easy manufacture. In this case, the protective cover can surround or enclose the sensor in a touching manner.

Alternatively, the protective cover can surround the sensor without touching it, in order to only protect it but not to influence it. In other words, this means in particular that the protective covers do not contact the sensitive area of the sensor, but surround it at a distance. Of course, the protective cover can be attached to a different location on the sensor. This ensures that if the protective cover burns off or shrinks, there will be no damage or residue left on the sensor.

A cylindrical protective cover for a sensor that can be shrunk and/or burned off by the action of heat also serves to solve the problem, with the protective cover consisting of (at least) one material that can be burned off essentially without leaving any residue or can be shrunk to the extent that the sensor is essentially exposed. The protective cover should be designed to be stable and fastenable to the sensor and/or its holder so that it can protect the sensor from mechanical loads, in particular lateral impacts etc.

The explanations of the method can be used to characterize the arrangements in more detail, and vice versa. The arrangement can also be set up in such a way that the method is carried out with it.

• 1: schematisch einen Schnitt durch einen Verbrennungsraum mit einem eingebauten Sensor mit Schutzhülle,
• 2: eine schematische perspektivische Ansicht eines Sensors mit Schutzhülle, und
• 3: einen schematischen Längsschnitt durch einen Sensor mit einer geschrumpften Schutzhülle.

Schematic exemplary embodiments of the invention, to which this is not limited, and the mode of operation of the method will now be explained in more detail with reference to the drawing. They represent:

• 1 : schematic section through a combustion chamber with a built-in sensor with a protective cover,
• 2 : a schematic perspective view of a sensor with protective cover, and
• 3 : a schematic longitudinal section through a sensor with a shrunken protective cover.

1 shows schematically a combustion chamber 2 of a heater 1, which can be operated in particular with hydrogen or a hydrogen-containing fuel gas. In such cases, instrumentation with at least one temperature sensor is often carried out. In the present exemplary embodiment, the combustion chamber has a housing 3 in which there is a door 4 (or flap) in which at least one sensor 5 is arranged next to a burner 11, in such a way that a measuring area 6 (the actual sensor) in the combustion chamber 2 protrudes and is held in a holder 7 . Leads 8 of the sensor 5 are also routed through the holder 7 . The sensor 5 has a protective cover 9 during its assembly up to the first combustion in the combustion chamber 2, which shrinks during the first combustion in the combustion chamber (typically in the direction of the holder 7) or burns essentially without residue. The latter is the preferred option, since the process is more reproducible than shrinkage. Nevertheless, the shrinking of the protective cover 9 is sufficient for the production of the full function of the sensor 5. The temperatures of 800 to over 1000° C. [degrees Celsius] that prevail in a combustion chamber during operation are far enough for the protective cover 9 to burn off or shrink if it is e.g. B. consists of plastic or cardboard.

2 shows a schematic perspective view of a sensor 5 with a protective cover 9, the protective cover having a support 10 on the holder 7 and thus being stable against lateral mechanical loads. The protective cover 9 is slid freely over the sensor 5 and does not touch it, which is particularly advantageous for shrinkable materials. Alternatively, however, the protective cover 9 can also be solid or filled with a material such as synthetic resin, that is to say completely envelop the sensor 5 . This increases stability, but does not change the combustibility. The measuring range 6 of the sensor 5 protruding into the combustion chamber 2 has a length L of z. 1 to 15 cm and a cross-sectional area QF of 0.5 to 25 mm ² , preferably 2 to 10 mm ² . In the case of round cross-sections, this means a diameter DS of the sensor of around 0.5 to 3 mm. The protective cover 9 has an outer diameter DH of z. B. 5 to 25 mm, preferably 10 to 15 mm. This also depends on the size of an opening into which the sensor 5 is installed, since it is installed with a protective cover 9 .

3 shows a sensor 5 with a protective cover 9 that has already shrunk, which has retracted in the direction of the holder 7 and essentially releases the measuring area 6 of the sensor 5, which protrudes into the combustion chamber (at least the part that is important for its function).

The present invention brings about comprehensive transport and installation protection for a sensor 5 for a combustion chamber 2 and allows error-free installation even under unfavorable space conditions when constructing a heating device.

Reference List

1

heater

2

combustion chamber

3

Housing

4

door

5

sensor

6

Measuring range (projecting into the combustion chamber)

7

bracket

8th

supply lines

9

protective cover

10

support/fixture

11

burner

L

length

QF

Cross sectional area

DS

diameter sensor

IE

Outer diameter protective cover

Claims (10)

Method for installing a sensor (5) in a combustion chamber (2), the sensor (5) being installed at its destination in a measuring area (6) protruding into the combustion chamber (2) and provided with a protective sleeve (9) that can be shrunk or burned off under the action of heat and then combustion is carried out in the combustion chamber (2), during which the protective cover (9) burns up or shrinks to such an extent that the sensor (3) is exposed. procedure after claim 1 , wherein the sensor (5) is a temperature sensor which is installed in a wall (3), door or flap (4) of a housing (3) of a combustion chamber (2) of a heating device (1). Sensor (5) for a combustion chamber (2), wherein the sensor (5) has a protective cover (9) that can be shrunk or burned off under the action of heat in a measuring area (6), which can be inserted when installed in the combustion chamber (2). can burn or shrink to such an extent that the sensor (3) is exposed. sensor (5) after claim 3 , wherein the sensor (5) has a holder (7) for attachment in a wall (3), door or flap (4) of a housing (3) of a combustion chamber (2). sensor (5) after claim 3 or 4 , wherein the protective cover (9) is supported on the holder (7) and the measuring area (6) that can be introduced into the combustion chamber (2) lies entirely within the protective cover (9). Sensor (5) according to one of claims 3 until 5 , wherein the measuring area (6) that can be introduced into the combustion chamber (2) has a length (L) of 1 to 15 cm and without protective cover (9) has a cross-sectional area (QF) of 0.5 to 25 mm ² . Sensor (5) according to one of claims 3 until 6 , wherein the protective cover (9) consists of plastic or cardboard. Sensor (5) according to one of claims 3 until 7 , wherein the protective cover (9) is cast or molded around the sensor (5). Sensor (5) according to one of claims 3 until 7 , wherein the protective cover (9) surrounds the sensor (5) without contact. Burnable or shrinkable cylindrical protective cover (9) for a sensor (5), the protective cover (9) consisting of a material which burns out without leaving any residue or can be shrunk under the action of heat to such an extent that the sensor (5) is exposed.

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