DE2309854C3 - Heat exchanger - Google Patents

Description

65

The invention relates to heat exchangers with a housing with inlets and outlets for separate Flows of hot and cold fluid and a matrix of heat transfer material, which comes in contact with the hot and cold fluid, and with one the temperature of the matrix monitoring detector.

In regenerative heat exchangers, there is a heat-storing material, usually in the form of a packed one Sheet metal in the flow path of a hot gas is heated up and then in the gap between them arranged, separate flow path of a cold fluid is moved In other designs the heat-storing mass is not moved, but the flow paths of the fluids are changed, see above that in any case the sheets heated by a hot gas transfer their heat to cooler air that is passed through or emit another cooler gas.

As the hot gases, usually exhaust gases, are passed through the heat exchanger, fly ash, unburned oil or soot can be deposited on the surface of the packed heat-storing sheets. These deposits can quickly grow to a level where the air or gas flow through the heat exchanger is partially blocked. When the temperature of the heat exchanger about 370 reached to 400 ⁰ C is exothermic produces heat to a point where the deposit begins to glow and a "hot forming spot," If this goes undetected its temperature is very rapidly to about 760 ° C at which the metal of the matrix of the heat exchanger ignites with catastrophic consequences for the neighboring structure.

It has been common practice with known heat exchangers (see e.g. British Patent Specification 12 26 466). Detectors to be provided for flames which signaled the occurrence of a fire. Such flame detectors however, only respond if a fire has already broken out or if the temperature has risen that far has that she has already been accompanied by a possibly destructive fire. Others on overheating devices that react to a rise in temperature of a flowing through the heat exchanger Fluids respond, but even in this case a temperature rise would only be noticed and could be corrected after the fire has reached destructive proportions

The invention is therefore based on the object of providing a heat exchanger with a warning device with the help of which the ignition of deposits can be detected at an early stage can that with appropriate measures, e.g. B. washing or cleaning the metal sheets, intervened against it in good time can be. It is therefore important to find the hot warriors before a harmful fire occurs do.

The above object is achieved according to the invention in that the detector is sensitive to changes in the Infrared radiation of the matrix responds

Advantageous refinements of the invention emerge from the subclaims.

The invention is explained below with reference to the drawings explained in more detail. It shows

F i g. 1 shows a side view of a rotary storage heat exchanger with a warning device according to FIG Invention,

F i g. 2 shows an enlarged detailed view of the warning device of the heat exchanger according to FIG. 1,

3 shows a partial side view, partly in section, of one

Heat exchanger with a modified warning device with a parabolic reflector,

4 shows a cross section through the parabolic Reflector according to FIG. 3 according to section line 4-4.

According to the drawing, the rotary storage heat exchanger shown consists of a cylindrical one Housing 10, which accommodates a rotor with a cylindrical rotor housing 14. The rotor is through radial Partition walls divided into a plurality of sector-shaped departments. It is indicated, for example, by a ι ο Motor 15 and a suitable reduction gear slowly rotated about its axis. The rotor contains a mass regenerative heat transferring material in the form of sheets 22 densely layered but between free flow paths that form channels for the fluids passed through. The heat transferring material first absorbs heat from the hot gases that come from a boiler or other heat source and through a Inlet port 24 enter and, after they pass through the heat transferring material have been passed, are ejected through an outlet port 26, in which normally a suction fan is arranged by the slow rotation of the rotor around its The axis becomes an element of the heat-storing material, which is heated by the hot gas has been, in a stream of a fluid to be heated, such as. B. cool air, moves through you Inlet port 28 enters the heat exchanger. This is then heated to the heated after it has been heated Elements of the heat exchanger ejected through an outlet port 32 and to the combustion chamber one Boiler plant or another point of use

During the start-up of a boiler or other heat-generating system from which the heat exchanger is supplied with hot exhaust gases, incomplete combustion in the burners can lead to unburned fuel and other unburned combustion products getting into the exhaust gas flow and then settling on the heat-storing material of the Deposit the heat exchanger. These deposits can build up and within a short time block or at least partially block the flow of air or another gas over the heat-storing material. At the same time, the temperature is gen of Ablagerun * and increase of these adjacent heat-storing material because it is no longer exposed to the cooling air flow when the temperature reaches to 370 to 400 ⁰ C, the process is exothermic and it is generated in the deposition heat to a point where the debris ignites. As a result, the metal of the heat exchanger will ignite when the temperature reaches approximately 760 ° C.

Experiments have shown that fires can begin as small hot spots 40 by the accumulation of debris near the center of the matrix where condensation of liquid vapors in the exhaust gases first occurs. These hot spots grow to about six inches in diameter and rise in temperature up to approximately 760 ^° C. When this temperature is reached, the material of the heat exchanger ignites and spreads very quickly to the adjacent structural parts of the heat exchanger with the result that the entire unit is destroyed.

Taking into account the fact that the deposits are initially within the body of the Heat exchanger take place and originally develop as harmless "hot warriors", a safety device was created according to the invention, which is suitable for determining the "hot spots" before a fire breaks out

According to the proposal, in the illustrated embodiment, a detector 36 for infrared rays is arranged on the side of the inlet connection 28 for the fluid to be heated «Infrared rays emanating from the body of the heat exchanger are directed in the reflector 38 onto the detector 36. The reflector 38 sits on a holder 40, soft by a screw spindle! 42 together with the reflector 38 ^; , n radial direction can be moved from the central to the edge area of the rotor and vice versa. The drive of the screw spindle is provided by a Mr.ior 44 and a reduction gear 46. The motor 44 can be operated in both directions of rotation, the control being such that the direction of movement of the reflector is reversed when it reaches the inner or outer edge of the rotor Has

While the rotor of the heat exchanger rotates around its axis, the reflector moves in radial direction across the rotor, so that the entire rotor is systematically close to the reflector is moved past and one after the other the entire rotor is searched through the reflector. The from a "hot bar" axially radiated energy, the rays of which are between those arranged at a distance heat-storing sheets of the heat exchanger through to hit the reflector, is used by this Detector reflected. If a signal is received there, it can be sent to an amplifier (not shown) be forwarded, switch on an alarm device, shutter or throttle flaps for cooling air or Open and close the water or even switch on a fire extinguishing system, which immediately reduces the fire hazard eliminated

In the case of large heat exchangers, two or more reflectors arranged at a distance can also be used on one single infrared detector, so that the matrix of heat-storing material more frequently on hot spots or possible fire is searched

A single parabolic reflector 52, which is fixed to the end of the rotor, has also proven to be practical is mounted and this spans radially so that it all radially from any point of the heat exchanger The reflector 52 throws the rays onto a collector 54 in his Focal point where the detector 36 is also arranged. The entire assembly, consisting of reflector and Detector, can be preassembled by the manufacturer in a single housing 56, one side 57 of which for Infrared radiation is permeable. Well-insulated wires 62 lead from the detector 36 to a not shown Reinforce outside the housing of the heat exchanger, creating countermeasures against it very quickly a hot bar can be induced.

As soon as the temperature at the detector 36 z. B. 93 ° C (200 ° F) coolant can be passed through a suitable cooling system, which includes Roh, ν 58 the housing 56 are guided.

In the manner described, the entire no

a rotary storage heat exchanger for air preheating during a single revolution be searched. The developing hot spots or fire are discovered very quickly, so that predetermined countermeasures can be initiated. While above an embodiment of Invention has been described in which the Safety device is arranged in the inlet port of the cold air, it goes without saying that the safety device can also be used in other inlet and outlet channels or Can be placed anywhere else where there is no excessive heating or corrosion is exposed.

For this purpose 2 sheets of drawings

Claims (11)

Claims; t. Heat exchanger with a housing with inlets and outlets for separate flows of a hot one and a cold fluid and a matrix of heat transferring material which is associated with the hot and cold fluid comes into contact, and with one the temperature of the matrix monitoring detector, characterized in that that the detector (36) is responsive to changes in the infrared radiation of the matrix (22) 2. Heat exchanger according to claim 1, characterized by one at one end of the matrix (14, 22) arranged, the infrared radiation on the detector (36) throwing reflector (38,52). ι s 3. Heat exchanger according to claim 2, characterized in that the reflector (38) is a flat mirror which can be moved along the matrix (14, 22) by means of a drive device (40-46) . 4. Heat exchanger according to one of claims 1 to 3, characterized in that the detector (36) is arranged unaffected by the hot and cold fluids on one side of the matrix (14,22) 5. Heat exchanger according to one of claims 2 to 4, characterized in that the reflector (52) is parabolic and with an axial spacing between them Matrix spanned 6. Heat exchanger according to claim, characterized in that the detector (54, 36) in the Focal point of the parabolic reflector (52) is arranged 7. Heat exchanger according to one of the preceding claims, the tüs Drefcopeicherwärmetauscher is formed, which is flowed through at the same time by a hot and a cold Püid characterized in that the reflector (38) periodically over the radius of the rotor (14) of the Rotary storage heat exchanger is movable 8. Heat exchanger according to one of the preceding claims, characterized in that the Reflector (38,52) in the inlet (28) for the cold fluid is arranged 9. Heat exchanger according to one of the preceding claims, characterized in that the heat-storing material (22) is in the form of metal sheets extending in the direction between Inlet and outlet (24, 26, 28, 32) extend and leave channels between them, the axially directed Do not obstruct the rays to the reflector (38, 52) arranged axially next to the rotor (14). 10. Heat exchanger according to one of the preceding Claims, which is designed as a rotary storage heat exchanger, which at the same time of one hot and a cold fluid is flowed through, characterized in that the reflector (52) and the detector (36) are installed in a housing (56, 57) which is in a one or Outlet nozzle (24,26,28,32) is arranged. 11. Heat exchanger according to claim 10, characterized in μ characterized «that the interior of the housing (56,57) is cooled by Kühlflüidleitüngeri (58).