SE462661B - SETTING AND DEVICE FOR MONITORING AND CONTROL OF A HEAT MEGENERATOR WORKING WITH A PULSE BURNING INCLUDING A HELMHOLTZ RESONATOR - Google Patents

Description

462 661 10 15 20 25 30 35 conventional combustion systems with open flame take place this usually with a photocell or ionization detector, but at the heat generator, which works with pulse combustion, it is both difficult and expensive to apply this type of monitoring.

For monitoring and control of it with pulse combustion operating heat generator in specified In this respect, registration of it has previously been arranged overpressure, which during operation is present in the combustion chamber and a thereby communicating pressure chamber on the valve downstream side. The pressure can then be transferred mechanically, pneumatically or hydraulically to an outside heat generator located control unit. This arrangements have not been reliable, and there have been problems with soot and oil leakage at the pressure outlet on the heat generator, which could have led until the control unit has been destroyed.

By another known method of monitoring and control of the heat generator a photocell has been used in the combustion chamber, which reacts to it below the combustion occurring radiation. The disadvantage of This arrangement is, first and foremost, the photocell easily soots again but also that it can give false signals by reacting to radiation other than that which originates from the flame in the combustion chamber and that it can interfere with its atomization and / or distribution injected the fuel. They have also let the optical the sensor or a sensor, including magnet and hall element, read the movement of the valve, but not either this arrangement is good, because the valve at a single explosion in the heat generator during start-up can get in vibration, whereby the sensor gives a false indication with accompanying shut-off of the starting fan and the igniter, before the heat generator is reached normal operating condition. In addition, the placement of ' 10 15 20 25 30 35 462 661 the sensor in the vicinity of an active part of the heat generator, that the assembly becomes complicated.

The invention has been added for the purpose of eliminating the above difficulties and inconveniences and provide a reliable indication of the normal operation of a heat generator with pulse combustion using a control systems as in relation to the previously known ones control systems are both simpler and more reliable.

The invention is based on the unique the relationship, that the Heat Generator of this intended the type works with a fairly constant and carefully determined pulse rate, usually in the range 60 ~ 100 Hz.

According to the invention, it is thus intended to achieve the stated purpose a way of controlling a med pulse combustion operating heat generator, which obtained the characteristics specified in claim 1, and a control device for practicing this method accordingly with the claim 8.

For a more detailed explanation of the invention, reference is made to the accompanying drawing, on which FIG. 1 is a schematic vertical sectional view of a pulse generator operating heat generator, FIG. 2 is a larger sectional vertical sectional view of the intake and combustion chambers for illustration of details in the execution, and FIG. 3 is a block diagram of the electronic the part of the control device according to the invention.

The one in FIG. 1 and 2 showed the heat generator of it the type referred to here, which works with pulse combustion according to known principle, is arranged in a water tank l0 with inlet 11 and outlet 12 for the water, as in known manner shall circulate in a thermal conductivity system for Waterborne heat. The heat generator includes a Helmholtz resonator with a resonant chamber 13 and one pulse tube 14, which is connected to the resonant chamber in its 462 661 10 15 20 25 30 35 one end. The resonant chamber forms the heat generator combustion chamber and is provided with a nozzle 15 for supply of gaseous, liquid or fluidized fuel via a solenoid valve 16 and with a spark plug 17, which is connected to an ignition transformer 17A. One suction 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 by a rhythmic movement alternately closing at overpressure in the combustion chamber and open in case of negative pressure in it.

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 one relaxation chamber 23 with exhaust pipe 24, which shall be connected to the chimney or other flue gas duct.

When the Heat Generator is operating during normal operation, the fuel injected into the combustion chamber 13 will ignited upon entering the hot combustion chamber and that incinerated in conjunction with that in the combustion chamber existing oxygen, whereby an overpressure occurs and the valve 20 closes under the influence of this overpressure.

At the onset of a subsequent negative pressure opens valve 20 again to let air into the combustion chamber from the intake chamber 18 with accompanying new ignition and combustion of fuel. It thus arises combustion pulses with a regular frequency in the combustion chamber.

The heat generator is operated intermittently depending on the temperature of the water in the tank lO on completely conventional way; upon attainment of a predetermined higher temperature on the water the Heat Generator stops to restart, when the temperature has dropped to one predetermined lower temperature. When restarting The heat generator after a standstill period must be external 'z 10 15 20 25 30 35 462 661 ignition of the fuel takes place by means of the spark plug 17 and the air must also be forced the suction chamber 18 by means of the starting fan 22.

The ignition device and the starting fan are thus started at the start but must then be stopped, 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 through negative pressure in the combustion chamber.

During normal operation of the heat generator occurs pressure variations in the communicating system which extends between the air inlet 21 and the exhaust outlet 24, and because the frequency of these pressure variations is within a very well defined frequency range, the pressure variations are used when applying the invention for controlling the heat generator. For the object is in the embodiment shown a sensor 25 arranged in the suction chamber 18 to sense those in the suction chamber during normal operation of the heat generator the pressure variations that occur. The sensor remains preferably of a piezoelectric crystal, since this is very reliable, but a sensor of a different type can be used in the practice of the invention. For example the sensor may comprise a membrane, which is affected by the pressure variations and the resulting movement read by an optical sensor, but this arrangement is more expensive than the piezoelectric sensor and in addition more complicated, while not being equal reliable. Another possibility is to detect the movement of the membrane by means of a wire strain gauge, but such an arrangement means a further increase in cost.

Inductive sensors mean another possibility though can give self-oscillation at low frequencies, which can disturb the control. Finally, the possibility of: use a microphone, in particular a carbon grain microphone, which sensor, which, however, is disadvantageous due to 462 661 10 15 20 25 30 35 that it can pick up ambient noise, which produces false indication in the control system.

The electrical signal obtained from the sensor 25 is supplied with an electronic system, which is shown in block diagram form in FIG. Because the signal at normal operation of the heat generator has a frequency in the range 60-100 Hz, the signal from the sensor must first pass one filter 26, which passes through frequencies between 30 and 200 Hz, whereby noise emanating from turbulence in the heat generator, noise in the surroundings and noise from the starting fan is separated from the signal. After reinforcement of the filtered signal in a signal amplifier 27 the frequency is measured in a circuit 28. The measured value compared with a prescribed frequency in a comparator 29, and the outcome is registered by a control device 30, which controls fuel supply, ignition and starting fan.

When normal operation is registered by the control device, i.e. in sufficient compliance with the prescribed frequency, the fuel supply is maintained through solenoid valve 16, while igniter 17, 17A and the starting fan 22 is switched off after a certain delay.

The control device 30 may be arranged to immediately start the ignition device and the starting fan, if the signal to the shut-off device would fall off, for example due to a malfunction.

It is to place the sensor 25 in the suction chamber most appropriate, as this is a "kind" environment, but other locations are conceivable. Thus can the sensor is instead placed in the pressure chamber, which is located on the downstream side of the valve 20 and in FIG. 2 is denoted 3l, where the environment is also favorable but where the location next to the valve and the injection nozzle may involve complicated assembly, while the sensor is not equally accessible for review and exchange. The sensor can also placed in the combustion chamber 13, the relaxation chamber 10 15 20 25 30 35 462 661 23 or the exhaust pipe 24, but the location in these places is less advantageous in view of the present one difficult environment. It showed the location of a piezoelectric sensor is thus the design which for is currently considered to be preferable for several reasons.

The electronic system can for achieving it described function is performed with components other than included in this as examples shown and described the execution.

Claims (6)

462 10 15 20 25 30 35 900112-AH-P \ A 661 PATENTKRKV A method for monitoring and controlling a heat generator operating with pulse combustion, 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 further the other end of the pulse tube is connected to a discharge chamber (23) with exhaust pipe (24), an intake manifold (18) with starting fan (22), a valve (20) controlled by the pulse pressure in the combustion chamber for regulating the connection (19) between the intake chamber and the combustion chamber , a device (15, 16) for injecting gaseous, liquid or fluidized fuel into the combustion chamber and an ignition device (17, 17A) for igniting the injected fuel into the combustion chamber, wherein during the operation of the heat generator generated pressure variations in the heat generator is sensed, characterized in that the pressure variations in the suction chamber (18) or systems communicating therewith are sensed, that the frequency of the pressure variations is compared with a predetermined frequency and that The ignition device and starting fan are switched off when the frequency of the pressure variations is sufficiently in accordance with the said predetermined frequency. 2. that only pressure variations above a predetermined minimum method according to claim 1, are known by strength. 3. A method according to claim 1 or 2, characterized in that the ignition device (17, 17A) and the starting fan (22) are switched off with a delay at sufficient compliance with said predetermined frequency. Monitoring and control device for carrying out the method according to claim 1 in a heat generator operating with pulse combustion, 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 thereof, a coupling chamber (23) with exhaust pipe (24), an intake chamber (18) with starting fan (22), a valve controlled by the pulse pressure in the combustion chamber, connected to the other end of the pulse tube (20) for regulating the connection between the intake chamber and the combustion chamber, a device (15, 16) for injecting gaseous, liquid or fluidized fuel into the combustion chamber, a sensor (25) for sensing the pressure variations generated in the heat generator during operation of the heat generator, and an igniter (17, 17A) for igniting the injected fuel in the combustion chamber, characterized by a comparator (29) for comparing the frequency of the pressure variations with a predetermined frequency. a device (30) controlled by the comparator for switching off the ignition device (16, 17) and the starting fan (22) in sufficient compliance with said predetermined frequency and that the sensor (25) is placed to detect pressure variations in the suction chamber. (18) or communication systems. 5. n a d in that the sensor (25) is constituted by a piezoelectric crystal. 6. T e c k n a d of a control device operatively connected to the sensor (25) according to claim 4, characterized by a control device according to claim 4 or 5, a characteristic circuit (28) for measuring the frequency of pressure variations.