NO170314B - DEVICE FOR LONG RINSE SHOES / BOOTS - Google Patents

Description

Combustion device.

The present invention relates to a combustion device,

in which a mixture of fuel and air is sucked in through an inlet to a combustion chamber, from which the gases are blown out at overpressure through an exhaust line.

The parts of the gas line that lie freely in the surrounding atmosphere or in rooms that communicate with the surrounding atmosphere involve a risk of leakage and off-gassing, which can lead to poisoning of the atmosphere, e.g. in a building, where there is thus a risk of exhaust gas poisoning.

The purpose of the invention is to provide a simple device which indicates that such a leak has occurred and/or which is designed to shut off the combustion device when such a leak of Cfr. 24k-8

the exhaust gases occur.

In order to achieve this, the incinerator according to the invention is characterized by the fact that the exhaust gas line is enclosed in a manifold which forms a gas collection chamber which, through a line, is connected to the inlet system for the appliance in a place where negative pressure prevails and is connected to a device which is. affected by the changes in the gas pressure in the said line due to leakage in the exhaust gas line. The device affected by the gas pressure can, in the event of a leak, be designed to affect an alarm device, such as e.g. a lamp or a bell, and/or influence an appropriate regulating device for the air or fuel for the appliance or for the electric ignition system if such is used, in order thereby to stop the combustion appliance.

The invention will be explained in more detail below with reference to the drawings showing an embodiment of the invention applied to an apparatus for pulsating combustion of the type described in detail in U.S. Pat. Patent Document No. 3-267,986. Fig. 1 shows a section through a combustion apparatus with a first and second combustion chamber.

Fig. 2 shows a schematic section through a hot water boiler,

in which the device according to the invention is built in as a heat source and at the bottom of which a cylindrical container is arranged which forms an expansion space for the exhaust gases from the device. Fig. 3 shows a schematic cross-section through the hot water boiler in fig. 2. Fig. 4 is a connection core for an automatic control system which includes a device for stopping the apparatus when exhaust gas leakage occurs.

As shown in fig. 1, the combustion device has an inlet 20,

a first and second combustion chamber 21, resp. 22, and an outlet 23, to which an exhaust line 24, 25 is connected (fig. 2).

At the end of a back cover 26 in the inlet, a base is attached which carries a coaxially arranged electric filament 27. The filament is used to ignite the fuel-air mixture when starting the apparatus. After the initial period, which lasts a few minutes, this filament is disconnected. The electrical connecting wires to this coil are indicated by the lines 28.

Another detail that emerges from fig. 1 is a line 29 which is connected to the inlet 20, but which can be connected at any other place in the inlet system, where negative pressure prevails due to the suction in the inlet 20 during operation of the appliance. The function of this vacuum line will be explained in more detail below.

The device in fig. 1 can be used for heating water in a hot water boiler 30- The exhaust gas line 24 from the appliance is connected to an expansion chamber Jl. This expansion chamber is suitably cylindrical, as shown. in fig. 2 and 3- The end part 32 of the exhaust line has a larger diameter than the line 24, so that a rudder part is formed which extends essentially tangentially through the chamber 31 wall 33 °S has its end 32a arranged near or in a plane which is arranged at right angles to the tangential direction and which extends through the central axis of the chamber 31. In this way, the exhaust gases will enter the chamber 31 °S providing a rotating flow, which is important for the pulsating combustion device to work satisfactorily. 1 The produced pulses entail an alternating positive and negative pressure. Because of the rotating flow, the gases will be recirculated, so that they pass the end 32a of the rudder part 32 from behind, whereby the negative phases of the pulsating flow will be filled in completely or partially. This makes it is possible to use a rather large resistance in the subsequent exhaust line, which means that the silencer 34 can have a small size. The gases enter the muffler in an area having several small holes, as indicated at the left end 35 of the muffler, and leaves the muffler through the exhaust pipe 25, which is surrounded by an exhaust collecting pipe 25a. This line communicates through hole 25b with the leakage gas-collecting chamber 37 below the cylinder 33", which chamber is closed above by means of transverse walls 36 °S and is closed below by means of a semi-cylindrical wall. Alternatively, the silencer can be arranged coaxially with the cylindrical chamber, and it is then preferably of the type with axial flow.

Fig. 4 shows a suitable connection which i.a. contains a circuit breaker 38 with a maneuvering arm 39 which in its closed position rests on a bimetallic spring 40. This bimetallic spring can be heated by

using current through a wire 41 when starting the device. After . for a predetermined period of time, the bimetallic spring 40 is heated and is then deformed so much that it is brought to a position where it releases the arm 39....

The electrical circuit's transformer is designated by 42.

The filament 27 is connected to the transformer 42 by means of wires 28, as shown.

A thermostat 43 and an electrically driven fuel pump 44 or an electromagnetic valve and a circuit breaker 45 are also connected in the circuit...

The thermostat 43 connects the circuit to the network 46 when the temperature of the medium to be heated has dropped to a predetermined value, and disconnects the circuit when this temperature has increased to a predetermined value. At the same time, resp. the pump is stopped 44«

The circuit breaker 45 has an arm 47 which is influenced by a pneumatic bellows 48", which bellows is connected through the line'29 so that it receives negative pressure from the inlet 20. The bellows is also connected to the semi-cylindrical leakage gas-collecting chamber below the expansion chamber Jl in fig; 3 using a wire 49*

This leakage gas-collecting chamber 37 communicates through hole-25b with the leakage line 25a which surrounds the exhaust line 25. When the apparatus is started, negative pressure will occur in the lines 29, 49, 37 and 25a, and this negative pressure forces the bellows to contract, so that the arm 47 follows this movement and breaks the current to the filament 27. If the device should not start, the bimetallic spring 40 will, after the predetermined start period, open the circuit breaker 38 before breaking the current to the pump 44"

If there is a leak in the exhaust system, then the negative pressure in the line 29, 49 will be reduced, so that the resulting pressure increase affects the bellows 48 which in turn affects the circuit breaker 45 before connecting the circuit. Thus, the filament 27 is switched on again, but after the predetermined start period, the bimetallic spring 40 will again open the circuit breaker 38 to stop the pump 44 or to close the corresponding solenoid valve. Thus, the lines 29, 49, 37, 25a and the bellows 48 form a simple dg-reliable guard to stop the device in the event of a leak in the exhaust system.

Although the invention is described in connection with its application to a special electrical connection system, it is clear that the pressure build-up in the vacuum system, which is formed by the lines 29, 49, 37 and 25a due to possible leakage in the exhaust gas system, can be used to act on any appropriate organ that is responsive to gas pressure variations to provide a warning signal, such as e.g. switching on an alarm lamp or a bell and/or to influence an appropriate control device for stopping the appliance. The line 29 must not be directly connected to the inlet 20, but can also be connected to any other place in the inlet system, e.g. the air cleaner, as long as there is only a negative pressure there due to the negative pressure in the inlet 20.

Claims (1)

1. Combustion apparatus with an inlet system for the intake of a mixture of air and fuel, a combustion chamber and an exhaust gas line, characterized in that the exhaust gas line (25) is enclosed in a collection tube (25a, 37) which forms a gas-collecting chamber, which chamber through a line (49" 29) is connected partly to the inlet system (2o) at the place where negative pressure prevails during the operation of the appliance, and partly to a device (48) which is influenced by the changes in the gas pressure in said line due to leakage in the exhaust gas line . 2. Apparatus according to claim 1, characterized in that the device which can be influenced by the gas pressure variations is designed to, in the event of increasing pressure in said line due to exhaust gas leakage, provide a stop of the apparatus and/or an influence of an appropriate warning device. 3. Apparatus according to claim 1, characterized in that the device which can be influenced by the gas pressure variations is made up of a pneumatic bellows (48). 4. Apparatus according to claim 1, characterized in that the device (48) which can be influenced by the gas pressure variations, when normal negative pressure has been achieved during the starting period, is arranged to influence a circuit breaker (45) before disconnecting an electrical control circuit for an electrical starting glow wire (27) which is arranged in the device's combustion chamber. 5- Apparatus according to claim 4, characterized in that a bimetallic spring (40) is arranged to influence a current switch (39. 38), so that this breaks the current after the start period, which results in the bimetal controlled circuit breaker disconnecting the current to the filament after a predetermined start period.