SE514161C2 - Method and apparatus for monitoring and controlling a pulse combustion heat generator - Google Patents

Abstract

The invention covers a method and a device for supervision and control of a heat generator with pulsating combustion. The amplitude of the sound generated during the operation of the heat generator is sensed by means of a sensor (25), and the initiation means (17, 17A, 22) or electrical operative system of the heat generator is shut down, when the amplitude reaches a predetermined value, which indicates that the heat generator operates, or falls outside a predetermined area, which indicates that the operation of the heat generator is defective.

Description

N U 20 25 30 514 161 '2 similar, but with a pulse combustion boiler it is associated with difficulties in arranging monitoring.

From SE-B-462 661 it is known to use the frequency of the pressure variations for this purpose. In this case, the pressure variations in the suction chamber are sensed, their frequency is compared with a predetermined frequency and the ignition device and the starting fan are switched off, when the frequency of the pressure variations shows sufficient correspondence with the predetermined frequency.

Using a frequency measurement in this way is fraught with certain problems and shortcomings. A boiler has a certain resonant frequency for physical reasons, and this frequency depends on the individual boiler's structure and temperature, fuel type and quality, as well as excess air, etc. The frequency does not give a clear indication of the function of the boiler; it would be beneficial to be able to get a clearer signal about how well the boiler is working. It has also been shown in practice that the method of frequency measurement has entailed major problems with a start that should have been approved not being so.

The invention A better way of monitoring and controlling a heat generator or boiler of the type in question is achieved according to the invention by sensing the amplitude of the sound and / or gas pressure generated during the operation of the heat generator and by switching off the heat generator starting means or electrical operating system when the amplitude reaches a predetermined value or falls outside a predetermined range.

In this case, the shutdown should take place with a certain delay, so that, for example, occasional pressure shocks and explosions in the boiler are not counted as approved times or do not lead to the boiler being switched off.

In a practical embodiment of a heat generator as above, the amplitude in the suction chamber is sensed and the ignition device and the starting fan are switched off when the amplitude reaches a predetermined value. A monitoring and control device for carrying out the method according to the invention has an electronic circuit device for emitting a signal for receiving from a sensor of an amplitude signal above a predetermined value or outside a certain range a signal for switching off the starting means of the heat generator and a signal for shutting down the heat generator's electrical operating system.

This circuit arrangement is preferably supplemented by a delay circuit. fire guard for the boiler, the electronic circuit device can be complete- To allow connection to a so-called with an adapter. The circuit arrangement can then be phantom-fed with current from the fire guard.

In the above-mentioned practical embodiment, the sensor can be arranged in the suction chamber and the starting means can be constituted by the ignition device and the starting fan.

The pressure connection of the sensor can in this case be provided with a snorkel, which extends down to the bottom of the suction chamber. Any leaking oil or water will thereby lead to the shut-off of the boiler, as the measured amplitude is thereby reduced.

The invention is based on the principle that the sensor senses the amplitude of the sound generated during combustion. The sensor therefore does not have to be located in the suction chamber of the boiler - even if it is the preferred location - but can alternatively be located in the combustion chamber itself, between the boiler body and the outer shell of the boiler or even completely off the forehead.

In the starting procedure for the boiler according to the current In the preferred embodiment, current is supplied simultaneously to the ignition device in the form of an electrode and to an oil pump with a starting fan on the same shaft, whereby an oil valve is also opened. When the approved start has taken place, the fan continues to run, 10 15 20 25 30 35 514 1e1l while the electrode is switched off. A two-stage oil pump can be used with lower oil pressure at start-up and higher pressure at operation. Variants of fan systems are conceivable to meet different requirements. This also applies to the ignition device. No gas pump is needed for gas boilers, but here safety valves etc. be.

When the boiler stops, the power supply to the oil pump and the oil valve is switched off. In some cases, post-ventilation with a fan can take place. The monitoring and control of the pulse boiler does not only have to apply to the starting process, but it can be just as important to switch off the boiler's electrical operating system, when the sensed amplitude falls outside a predetermined range, which indicates that there is something wrong with the boiler's operation.

The invention is applicable to all types of heart rate boilers and is not limited to use in the embodiment chosen, for example.

There is reason to believe that the control of pulse boilers will be computerized, but the invention is also applicable in such cases.

List of drawings The invention will be described in more detail in the following with reference to the accompanying drawings, in which Fig. 1 is a very schematic vertical sectional view of a pulse combustion heat generator and Figs. 2 and 3 are block diagrams of two embodiments of monitoring and control devices according to the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS The heat generator of the type intended here shown in Fig. 1, which operates with pulse combustion according to known principle, is arranged in a water tank 10 with inlet 11 and outlet 12 for the water, which in a known manner is to circulate in a heat pipe system for waterborne heat. The heat generator comprises a Helmholtz resonator with a resonant chamber 13 and a pulse tube 14, which is connected to the resonant chamber at one end. The resonant chamber forms the combustion chamber of the heat generator and is provided with a nozzle 15 for supplying gaseous, liquid or fluidized fuel via a solenoid valve 16 and with a spark plug 17, which is connected to an ignition transformer 17A. An intake chamber 18 is connected to the combustion chamber through an air inlet 19, which is controlled by a valve 20. The valve is arranged to operate automatically to alternately close in the event of an overpressure in the combustion chamber and open in the event of a negative pressure in the combustion chamber through a rhythmic movement. The intake chamber communicates with the outside air through an inlet 21, which is provided with a starting fan 22, via silencers and / or filters.

The other end of the pulse tube is connected to a relaxation chamber 23 with an exhaust pipe 24, which must be connected to the chimney or other flue gas duct.

When the heat generator operates during normal operation, the fuel injected into the combustion chamber 13 will ignite upon entering the hot combustion chamber and be burned in conjunction with the oxygen present in the combustion chamber, whereby an overpressure arises and the valve 20 is closed under the influence of this overpressure. Upon the onset of a subsequent negative pressure, the valve 20 is reopened to allow air into the combustion chamber from the intake chamber 18 with subsequent re-ignition and combustion of fuel.

Thus, combustion pulses occur with a regular frequency in the combustion chamber.

The heat generator is operated intermittently depending on the temperature of the water in the tank 10 in a completely conventional manner; the water, the heat generator is stopped to start eating, when a predetermined higher temperature is reached when the temperature has dropped to a predetermined lower temperature. When restarting the heat generator after a standstill period, external ignition of the fuel must take place by means of the spark plug 17 and the air must also be forcibly supplied to the intake chamber 18 by means of the starting fan 22.

The ignition device and the starting fan are thus switched on at the start, but must then be switched off when the heat generator has reached normal operation, by which is meant here that the fuel ignites itself and that the air is sucked in by negative pressure in the combustion chamber.

An example of a monitoring and control device for the heat generator or boiler shown with reference to Fig. 1 is shown in Fig. 2. A sensor 25 is, as shown in Fig. 1, arranged in the wall of the suction chamber 18. The sensor 25 is intended to sense the amplitude of the sound and / or the gas pressure present in the suction chamber. The sensor 25 is preferably of the piezoelectric type, but other types can also be used.

Through a connection 25 'into the suction chamber 18 to which the highest or lowest sound is memorized in the sensor 25. Memories 26 and 27, the signals from the sensor 25 are fed, the lowest sound pressure recently measured, i.e. the highest and lowest signal fed from the sensor 25 If a signal lower than the highest or higher signal than the lowest is fed to the memories 26 and 27, the memorized values are gradually changed to the new input values.

Signals corresponding to the highest and lowest pressures are fed from the memories 26 and 27 to a differentiator 28, where the lowest value of the signal is subtracted from the highest value, so that a signal corresponding to the signal amplitude is fed to a further differentiator 29. In this the amplitude signal obtained is compared with a set minimum value to give an output ready signal if the amplitude signal, ie the amplitude of the sensor 25, is above the set minimum level.

A device of the type described can be called an amplitude monitor.

Fig. 3 shows a version developed in relation to the amplitude monitor according to Fig. 2. The above description of an- 10 15 20 25 30 2514161; 7 the order until the output signal from the differentiator 29 is the same. This output signal is in this case fed to a delay circuit 30, which has the function of only releasing set. In this way, individual pressure surges do not pass through otherwise approved signals with a certain duration. or explosions in the heat generator to be counted once.

It is common for the operation of a standard heat generator, which can use a photocell as a sensor. It may be appropriate for an approved rator or boiler to be monitored by means of a so-called to be able to use such a fire guard for pulse boilers of the type described above, which is approved and cheap thanks to mass production. In order to be able to connect the amplitude monitor according to the invention directly to such a fire monitor, it is required that the output draws a lot of current at an approved amplitude and a little current at an unapproved amplitude. This is controlled by a unit 31, which emits a signal 32 directly to a photocell input of the fire guard (not shown).

The device can be supplemented with a so-called phantom supply 33, which means that, for example, a sensor can receive its power supply through the same conductor where it leaves its signal. In this way, the current that the fire guard normally emits to read the otherwise connected photocell can be used as the driving current for all electronics in the amplitude guard. Separate power supply is thus avoided, which leads to a small amplitude monitor circuit with easy connection and low cost.

The device will also be independent of the mains voltage used.

The pressure connection 25 'of the sensor 25 can be provided with a snorkel 33, which is located in the suction chamber 18 of the boiler and extends down to its bottom. If, due to a fault, liquid leaks into the suction chamber 18 and the liquid enters the snorkel 33, the measured amplitude decreases drastically, which due to the function of the amplitude monitor leads to shut-off of the boiler, since approved passage cannot be indicated. 514 ml 514 The amplitude monitor according to the invention is suitably given a mechanical construction for mounting together with the sensor at a suitable measuring point. This facilitates installation and avoids the frequency dependence that, for example, a connection hose would give rise to.

The practical embodiment described above is connected to a commercially available heat generator operating with pulse combustion. However, other such heat generators are conceivable for the device according to the invention.

Thus, designs with one or more pulse pipes, exhaust chambers, exhaust pipes and / or valves are conceivable.

Furthermore, it is possible in some cases to do without a starting fan, and if the heat generator is equipped with a starting fan, it may not need to be switched off after the starting process. In the embodiment shown, the ignition device consists of a spark plug, but alternatives such as glow means are possible. The fuel injection device may be a carburetor or injector instead of a nozzle. The relaxation chamber may finally be connected to a bubble chamber or the like instead of an exhaust pipe or a chimney.

Claims (9)

W U 20 25 30 PATENTKRAV 1. Methods for monitoring and controlling a heat generator operating with pulse combustion, characterized in that the amplitude of the sound and / or gas pressure generated during the operation of the heat generator is sensed and that 17A, 22) when the amplitude reaches the setting of the heat generator. starting means (17, or electrical operating systems occur, a predetermined value or falls outside a predetermined range. 2. A method according to claim 1, that the adjustment takes place only when the amplitude with a characteristic, certain, determined duration has reached the predetermined value or fallen outside the predetermined range. A method according to claim 1, in a heat generator, comprising a Helmholtz resonator with a resonant chamber (13) arranged as a combustion chamber, a pulse tube (14) connected to the combustion chamber at one end, a decoupling chamber (23) connected to the other end of the pulse tube. with a drain pipe with a starting fan (22), a valve (20) controlled by the pulse pressure in the combustion chamber for (24), a suction chamber (18) regulating the connection (19) between the suction chamber and the combustion chamber, a device (15, 16) for injection of fuel in the combustion chamber and an igniter (17, 17A) for igniting the fuel, characterized in that the amplitude in the intake chamber (18) is sensed and that 17A) and possibly the starting fan (22) when the amplitude reaches a predetermined value. the igniter (17, shut down, Monitoring and control device for carrying out the method according to claim 1 in a heat generator operating with pulse combustion, characterized by an electronic circuit device (26-29) for indicating upon receipt from a sensor (25) of a signal an amplitude above a predetermined value or outside a certain range emits a signal for shutting down the heat generator WU 20 25 30 514 161) '; f 10 starting means (17, 17A, 22) and a signal for shutting down the electric generator's electrical operating system. Device according to claim 4, characterized in that the electronic circuit device (26-29) is supplemented by a delay circuit (30). Device according to claim 4, characterized in that (26-29) is supplemented with a unit (31) for adaptation to a so-called electronic circuit device fire guard for the heat generator. Device according to claim 6, characterized in that the electronic circuit device (26-29) has a so-called phantom supply (33) of current from the fire guard. Device according to any one of claims 4-7 in a heat generator comprising a Helmholtz resonator with a resonant chamber (13) arranged as a combustor for a combustor, combustion chamber, the chamber connected at its one end pulse tube (14), the other end of the pulse tube connected relaxation chamber (23) with an exhaust pipe (24), an intake chamber (18) with a starting fan (22), a valve (20) controlled by the pulse pressure in the combustion chamber for regulating the connection between the intake chamber (15, reindeer and the combustion chamber, a device 16) for injecting fuel into the combustion chamber and an ignition device (17, 17A) for igniting the injected fuel into the combustion chamber (25) is characterized by the fact that the sensor is arranged in the suction chamber (18) and that the starting means consist of the ignition device (17, 17A) and the starting fan (22). k ä n n e t e c k n a d (25) has one Device according to claim 8, wherein a pressure connection (25 ') of the sensor snorkel (33) extending down to the bottom of the suction chamber (18). hence,