DE10236231A1 - Dust loaded gas flow temperature sensor for coal fired power plant, has cheap moulded impact protection rod containing sensor tube and abrasion detection wires - Google Patents

Abstract

A dust loaded gas flow temperature sensor (30) lies in a tube (18) in a groove in the downstream side of an impact protection rod (12) with hardened moulded, concrete, ceramic or basalt cover (16) and abrasion detector (20) wire (22, 24) upstream from the sensor (30) with both held perpendicular to the gas flow in a flange (10).

Description

The invention relates to a device for measuring the temperature in a gas stream contaminated with dust with a temperature sensor and an upstream of the temperature sensor, the temperature sensor at least partially enclosing Baffle rod and a flange for holding the temperature sensor and of the baffle rod essentially transversely to the flow direction, in which in the baffle rod essentially parallel to the temperature sensor and in the direction of flow seen at a distance from this one extending along the baffle wear sensor is provided, which responds when the baffle rod by abrasion to the abrasion sensor is worn.

Such temperature sensors will be used for example in coal-fired power plants. The coal is finely ground and from an air stream into the combustion chamber of a Boiler transported. The temperature of the coal in the air stream among other things influenced by the moisture of the coal. to The temperature is raised to achieve defined combustion processes regulated a predetermined value. The temperature sensor is the sensor of Regulation.

The coal dust in the air flow has considerable abrasive effect. The one protruding into the airflow temperature sensor would therefore soon inoperable due to abrasion become. Therefore, an upstream of the temperature sensor the temperature sensor at least partially enclosing Baffle rod provided. This baffle rod protects the temperature sensor the abrasion. The impact rod itself is abraded with the Time worn out. An essentially cylindrical impact rod is used into a knife-like body with one of the flow opposite edge removed. This abrasion must be monitored to damage of the temperature sensor to prevent.

Through the DE 33 01 886 C2 and the DE 100 29 896 C2 Devices for measuring the temperature in a gas stream laden with dust are known, in which the temperature sensor is protected by an impact body made of steel. To monitor the abrasion of the impact body, a blind hole extending along the impact body, which is filled with a pressurized pressure medium, is provided in the impact body upstream of the temperature sensor and at a distance from it as an abrasion sensor. This pressure is monitored by a pressure sensor. When the abrasion of the impact body reaches the blind hole, the pressure of the pressure medium collapses. The pressure sensor then signals that a critical abrasion of the impact body has been reached and that the impact body must be replaced soon.

The impact body is a wearing part. He should be made of highly abrasion-resistant steel. Such a steel part is expensive. There are applications where the abrasion is very strong. The applies to, for example Lignite-fired power plants, where the coal has a significant amount of sand has caused strong abrasion.

The invention is based on the object a device for measuring the temperature in a dust loaded gas stream a cheaper baffle provided.

The invention is further the object based on the abrasion resistance of the impact body to the abrasive properties to adjust the dust in the gas flow.

According to the invention, this is the case with a device of the type mentioned in that the impact rod has a jacket has the with a hardening sealing compound is poured out.

The casting compound can be concrete, ceramic or be a basalt material. An impact body constructed in this way is cheaper as an impact body made of high-strength steel. The potting compound can be chosen according to the requirements.

In the above-mentioned known devices shows the metallic impact body on the downstream Side a groove. The temperature sensor sits in this groove, see above that he in heat exchange can stand with the gas flow. In the case of an impact body with casting compound in the coat lengthways the downstream Wall of the jacket a pipe can be cast in the downstream wall and a longitudinal groove be milled into the tube at least over part of its length and the temperature sensor out in the pipe and in the area of the longitudinal groove in heat exchange be with the gas flow.

The attachment and training of the wear sensor must on the other structure of the impact body can be adapted. It is not possible, in a concrete body make a blind hole and fill it with pressure medium. Out for this reason, the abrasion sensor is preferably one that is cast into the casting compound electrical sensor. The abrasion sensor can one along of the impact body extending insulated wire that is broken by abrasion when the impact body down to the wire. The wire is in a suitable one electrical circuit that gives a signal when the wire is broken supplies. The wire can be U-shaped in the impact body with one leg of the Flange to the free end of the impact body and with another Thigh back guided his. It is blowing the cutting-like removal of the impact body is useful if the two legs of the wire symmetrical to one parallel to the flow direction longitudinal median plane of the impact body are arranged.

The electrical sensor can once a first readiness display immediately on the Flange and on the other hand transmit one second operational readiness indicator can be controlled in a control room.

An embodiment of the invention is explained in more detail below with reference to the accompanying drawings.

1 shows a side view of a device for measuring the temperature in a dust-laden gas stream.

2 shows a view from the right in 1 ,

3 shows a view of the device from above in 1 ,

4 shows a view from the right in 3 ,

5 shows the temperature sensor for itself.

6 shows the impact body and the flange itself.

7 shows a view of the flange from the left in 6 with the connecting plugs to be screwed into the flange.

In 1 10 denotes a flange of the device which is fastened to the wall of a channel in which a gas stream laden with dust flows. On the flange 10 is an impact body 12 of cylindrical basic shape by means of an impact flange 14 attached. The impact body 12 has a cylindrical jacket 16 from sheet metal. In the cylindrical coat 16 is a pipe 18 inserted and on the inner wall of the jacket 16 spot-welded. The pipe 18 extends along the downstream inner wall of the jacket 16 , ie above in 1 along the entire jacket 16 , Furthermore, an abrasion sensor in the form of a U-shaped wire is in the jacket 20 arranged. The wire 20 runs with one leg 22 from the flange 10 to the free end of the impact body 12 and with one leg 24 back to the flange 10 , The two legs 22 and 24 are upstream of the pipe 18 symmetrical to a central longitudinal plane running parallel to the gas flow 26 , The wire is covered with glass fiber or another temperature-resistant material.

The coat 16 comes with a potting compound 28 poured out. The casting compound can be concrete. The casting compound can also be ceramic or a basalt material. The type of potting compound can be adapted to the properties of the dust carried in the gas stream. By pouring out the position of the pipe 18 and the wire 20 in the coat 16 fixed.

In the pipe 18 becomes an elongated temperature sensor 30 inserted The temperature sensor 30 has a measuring element at its end 32 , for example a thermocouple. The connections of the measuring element 32 are in a tube 34 guided and in the usual way with a measuring head 36 connected. The temperature sensor 30 is through one with a hole 38 ( 7 ) provided plug in turn in a hole 40 of the flange 10 is firmly connected. The connector plug 38 has a recess 42 on the connecting links 44 between the pipe 34 of the temperature sensor 30 and the measuring head 36 receives.

The temperature sensor 30 thus extends with his pipe 34 and the measuring element 32 through the cast pipe 18 , To ensure thermal contact between the measuring element 32 and to ensure the gas flow is in the jacket 16 and the pipe 18 in the area of the measuring element 32 a groove 46 milled. The measuring element is then in the 1 right end of the tube 18 , which is connected to the gas flow via the groove.

In a hole 48 of the flange 10 is a plug 50 firmly connected. The connector plug has a hole 52 on. The two legs 22 and 24 of the wire 20 are through the hole 52 to an evaluation and display device 54 guided. The evaluation and display device 54 contains a circuit that is based on breaking the wire 20 responds. Two indicator lights 56 and 58 signal whether the device is still operational, the wire 20 is intact or whether the wire 20 is interrupted. The latter signals that the impact body 12 must be replaced at the next opportunity. The displays are simultaneously via a cable 59 transmitted to a control room as a remote signal.

Claims (10)

Device for measuring the temperature in a dust-laden gas stream with a temperature sensor ( 30 ) and an upstream from the temperature sensor ( 30 ) arranged, the temperature sensor ( 30 ) at least partially surrounding impact rod ( 12 ) and a flange ( 10 ) for holding the temperature sensor ( 30 ) and the impact rod ( 12 ) essentially to the direction of flow, in which in the baffle rod ( 12 ) essentially parallel to the temperature sensor ( 30 ) and seen in the direction of flow at a distance in front of it along the baffle rod ( 12 ) extending abrasion sensor is provided, which responds when the impact rod ( 12 ) is removed by abrasion to the abrasion sensor, characterized in that the impact rod ( 12 ) a coat ( 16 ) with a hardening casting compound ( 28 ) is poured out. Device according to claim 1 , characterized in that the casting compound is concrete. Device according to claim 1, characterized in that the potting compound is ceramic is. Device according to claim 1, characterized in that the casting compound is a Basalt material is. Device according to one of claims 1 to 4, characterized in that (a) in the jacket ( 16 ) along the downstream wall of the jacket ( 16 ) a pipe ( 18 ) is cast in, (b) in the downstream wall and the pipe ( 18 ) a longitudinal groove at least over part of its length ( 46 ) is milled and (c) the temperature sensor ( 30 ) in the tube ( 18 ) and in the area of the longitudinal groove ( 46 ) is in heat exchange with the gas flow. Device according to one of claims 1 to 5; characterized in that the abrasion sensor is inserted into the casting compound ( 28 ) cast-in electrical sensor ( 20 ) is. Device according to claim 5, characterized in that the abrasion sensor extends along the impact body ( 12 ) extending wire ( 20 ), which is interrupted by abrasion when the impact body (12) reaches the wire ( 20 ) is removed. Device according to claim 7, characterized in that the wire ( 20 ) in the impact body ( 12 ) U-shaped with one leg ( 22 ) from the flange to the free end of the impact body ( 12 ) and with another leg ( 24 ) is led back. Device according to claim 8, characterized in that the two legs ( 22 . 24 ) of the wire ( 20 ) symmetrical to a longitudinal median plane running parallel to the direction of flow ( 26 ) of the impact body ( 12 ) are arranged. Device according to one of claims 6 to 9, characterized in that a first readiness display ( 54 . 56 . 58 ) directly on the flange ( 10 ) and secondly, a second operational readiness indicator can be controlled remotely in a control room.