DE1095444B - Device for starting, regulating and monitoring combustion systems - Google Patents

Description

Device for starting, regulating and monitoring combustion systems The invention relates to a device for starting, regulating and monitoring of combustion systems in which a switch for an electrically operated fuel feed device by a bimetallic element, the heating resistor of which with an electrical ignition device is connected in parallel, is closed at start-up and by an on the flame formation responding in the furnace and thereby switching off the excitation circuit of the heating resistor Actuating element is held in the closed position.

A device of this type is known, but it is designed in this way is that there is a possibility that if a malfunction occurs in the apparatus the heating resistor of the bimetal element continues to flow through the current and over the switch closed by him for the fuel feed device the fuel supply is maintained without a flame forming, which causes the shutdown of the excitation circuit of the heating resistor should switch off, resulting in a dangerous Condition would result.

The object of the invention is in a device of to ensure the aforementioned type by a very simple and reliable means, that if a fault occurs, any of the electrical Parts of the device is prevented with security.

This object is achieved in that, according to the invention, the bimetal element is coupled to a further switch, which is activated in the event of prolonged heating of the bimetallic element supplies the current to the fuel feed device, to the heating resistor of the bimetallic element and the electrical ignition device interrupts and the only can be switched on again by manual operation.

In an expedient embodiment of the invention, this can affect the flame formation attractive actuating element a helically wound bimetallic element or a photocell that controls an electromagnet. Such actuators are known per se.

Another advantageous embodiment is achieved in that the switch operated by the thermostat is an additional heating resistor for the Bimetal element is connected in parallel with a switch arranged in series, which is operated in the same direction as the switch of the fuel feed device.

The invention is illustrated below with reference to the drawing, for example explained in more detail.

Figs. 1 to 3 show schematically various embodiments of the invention in which the responsive to the flame actuating element is a bimetal element; Figure 4 shows a schematic of a further embodiment in which the actuator responsive to flame formation is a photocell; FIGS. 5 and 6 show in front view and in side view, respectively, a control device which operates according to the scheme of FIGS. 1, 2 and 3; FIG. 7 shows a modified embodiment of this control device, which operates according to the diagram of FIG.

In Fig. 1, a switch 1 is shown in the circuit of a motor 2, which takes care of the C51 and air supply. This switch that is out of order is open is, is designed so that when starting the furnace by working a electrically heated bimetal strip 3 is closed.

The circuit includes a heating element 4 for this bimetal strip within the control device, the switch 6, which is closed when starting.

In the line to the controller are a thermostat switch 7, which is on the to be controlled temperature responds, and the switch 5 is arranged.

An ignition transformer 8 is parallel to the bimetal heating element 4 switched.

A device 9 which responds to the flame and which essentially consists of a bimetallic spiral is connected to the switch 1 and is designed in such a way that it keeps the already closed switch 1 closed at a higher temperature regardless of the subsequent movement of the electrically heated bimetal 3.

The switch gives a lower temperature when there is no flame 1 free, whereby the engine 2 is switched off.

The device 9 responsive to the flame is still with the Switch 6 connected and opens this switch when the temperature rises. Through this the ignition transformer and the heating element 4 are switched off.

If the burner does not ignite, the switch 6 is activated by the device 9 not actuated, and continued heating of the bimetal element 3 opens the second, usually closed switch 5, which, since it is in the main line is arranged, turns off the burner.

The latter switch 5 must be turned on manually before the burner can be restarted.

This simple scheme creates under normal working conditions working with safety, but does not protect against failure of the Flame appealing facility.

It is not possible to provide protection against flame failure to be given if the flame fails at the same time during a run to which the flame responsive device should first fail. However, such protection can be achieved by modifying that shown in FIG Facility to be given.

In this modified embodiment shown in FIG. 2, a switch 10 and a heating resistor 11 are installed. The switch 10 is usually open, but is closed simultaneously with the operation of the switch 6 by the element 9 responding to the flame. The resistor 11 is provided in order to heat the bimetal strip 3. If, therefore, damage to the element 9 causes the switch 1 to be kept closed after the burner has been switched off by opening the control thermostat 7, heated, since the switch 10 is also kept closed, the resistor 11, the bimetal element 3, and this thus opens the switch 5.

In a modified embodiment of the mechanical holding device for the switch 1, the embodiment shown in Figure 3 uses an electromagnetic one Circuit 13 through which current flows through a second contact on switch 6 can be. Such a design gives protection against instantaneous failure the supply, because after the release of the electromagnetic circuit the switch 1 opens and only closed again by the action of the bimetal element 3 can be. A proper restart with ignition is therefore required after a temporary Interruption of the supply guaranteed.

Since the switch 1 is held electromagnetically in this embodiment is, damage to the flame-responsive device 9 stops the Switch 1 after switching off the burner by opening the control thermostat 7 not closed because switch 7 disconnects the circuit. The switch 10 and the bimetal heating element 11 can therefore be omitted if necessary. If switch 6 fails, it does not return to its "cold" contact when the burner is switched off by the thermostat 7. A re-run of the Burner is not possible because the heating element 4 for the bimetal 3 is not excited. In Fig. 4, the bimetallic device responsive to the flame is represented by a simple one Photocell 15 replaced as it is by a cadmium-sulfur compound or a Cadmium selenium cell is created, the resistance of which has a strong decrease in value when exposed to light. A transformer 14, the primary winding of which is excited via the switch 5, supplies the necessary low voltage on the secondary side to work the electromagnetic holding coil 13, which the motor switch 1 at Presence of a flame in the furnace after its initial closure the bimetal 3 keeps closed. The switch 6, which the power supply to the bimetal heating element 4 and to the ignition transformer 8 is also made possible by energizing the coil 13 opens when the presence of a flame in the furnace causes the photocell 15 becomes conductive.

According to the embodiment of FIGS. 5 and 6, in accordance with the embodiment of FIG. 1, the switch 1 is shown as a resilient contact 20 which cooperates with a fixed contact 21. The bimetallic strip 3 is designed into a U-shape 22 and is arranged so that a spindle 23 passes between the legs of the U. This U-shaped bimetal is free to move at each end and is connected to a base by a resilient strip 24 attached to the bimetal approximately midway along its length and to the base at 25. A winding of the heating element 4 is wound on an insulating tube 36 and arranged in the U of the bimetallic strip. The circuit breaker 5 is shown as a fixed contact 26 and as a movable contact 27. This latter contact is flexibly arranged on a connecting arm 28 and cooperates with a snap device 43 which holds the contacts 26 and 27 in the open position when they are actuated by the bimetal arm 22, which requires manual readjustment.

The switch 6 is shown as a resilient contact 29 which works together with a contact 30. The actuating element 9, which responds to the formation of a flame, is shown as a spiral which is arranged behind a switchboard 32 and connected in such a way that it works on the spindle 23 . Rotation of this spiral as the temperature changes actuates switches 1 and 6 through a sliding coupling device 33 which is carried on spindle 23 and which arms 34 and 35 actuate.

In the standby position for starting, the disconnector 5 (contacts 26, 27) is closed and so is the switch 6 (contacts 29, 30). Switch 1 (contacts 20, 21) is open. When the control switch 7 is closed, the heating element 4 and also the ignition transformer 8 are excited. The rising temperature from the heating element 4, which acts on the bimetal 3, causes the open ends of the U to tend to separate from one another. One end presses on the pin 37 carried by the arm 34, this pin moves the contact 20 so that it comes into engagement with the contact 21, whereby the circuit to the oil burner motor 2 is closed. If the flame arises, the increasing temperature around the bimetal spiral 9, which rotates the spindle 23, tends to move the arms 34, 35 counterclockwise. This tendency to move the arm 34 presses the pin 37 against the switching sheet of the contact 20 and keeps it in contact with the contact 21 and therefore keeps the oil burner motor running. A further rotation of the spiral causes the pin 38 on the arm 35 to press on the beveled end of the switching blade 29 and the contacts 29 and 30 are interrupted. As a result, the ignition transformer 8 and the bimetallic heating element 4 are switched off. The subsequent cooling of the bimetal 22 causes a working end to move back out of contact with the pin 37. The switch 1 (contacts 20, 21) remains closed by the pressure of the bimetallic spiral 9 as long as the flame is maintained in the furnace. If the flame should not arise, a counter-rotation of the spiral 9 releases the pressure on the pin 37, and the motor switch 1 opens.

The clockwise movement of the arm 35 as the temperature falls in the furnace is by an idle device between the bimetallic spiral 9 and the clutch disc determined so that the switch 6 is closed after a delay is to the circuit of the bimetal heating element 4 and the ignition device 8 again close. The sequence as described above is then repeated. If the flame should not arise, the end 22 of the U-shaped bimetal moves towards switch 5. A setting of the time period before shutdown is obtained by means of a screw 39 which is rotatable in the bimetal arm 22 a thread is attached.

If the electromagnetic holding device of Fig. 3 is selected, become the arm 34, which is operated by the sliding clutch 33, and the bimetallic spiral 9 replaced by an electromagnet whose pole piece 40, when energized, the switch 1 holds closed by tightening the armature 41, which is on an extension of the Switching arm 20 is worn. A second fixed contact 42 works with the contact 29 together when the switch 6 acts on the bimetallic spiral due to the effect of the resulting flame 9 is moved to complete the circuit of the electromagnet 13.

The switch 10 of FIGS. 2, 3 and 4 is not in FIGS. 5 and 6 shown, but could consist of a second flexible element associated with it Contacts exist which are carried under insulation on the sheet 29 of the switch 6 and move with this switch. The heating coil 11 would then open the same tube as the heating element would be wrapped and would therefore be the bimetal 3 affect how it is done by the heating element 4.

In the implementation of the circuit of FIG. 4, this is on the flame responsive element 9, which is shown as a bimetal spiral in Fig.6, through replaces the photosensitive cell 15 according to FIG.

An embodiment of such an arrangement is shown in FIG. The start-up circuit of this embodiment is the same as that in FIGS. 5 and 6, but here is the one responsive to the flame Bimetal strip 9 replaced by the light-sensitive cell of Fig.4. When arising of the flame causes light falling on cell 15 to generate a current in the solenoid coil 13 flows. The resulting magnetization of the core 40 holds the armature 41, which closes the contacts 20, 21 in the circuit of the fuel feed motor holds and opens switch 6 (contacts 29, 30) by tightening armature 44, to interrupt the ignition circuit and switch off the heating of the bimetal arm 22. Failure of the flame to occur during start-up leaves the energy supply to the Bimetal heating element 4, from which a continued movement of this bimetal results in order to hit the switch 5 (contacts 25 to 27).

Failure of the flame during a pass de-energizes the electromagnet 13, whereby both armatures 41 and 44 are released. This opens switch 1 (contacts 20, 21), which switches off the fuel feed motor and enables switch 6 (contacts 29, 30) to close again in order to close the circuit of heating element 4 and ignition device 8 again. After a time delay, the control closes the switch 1 again, as a result of which the circuit of the fuel feed device 2 is closed again and the start-up circuit proceeds as described above.

Claims (4)

PATENT TO SPRCCFIE: 1. Device for starting, regulating and monitoring combustion systems, in which a switch for an electrically operated fuel feed device is closed during start-up by a bimetal element, the heating resistor of which is connected in parallel with an electrical ignition device, and by a Flame formation in the furnace responding and thereby the excitation circuit of the heating resistor is held in the closed position, characterized in that the bimetallic element (3) is coupled to a further switch (5) which, if the bimetallic element (3) is heated for a longer period of time, the current The fuel feed device (2) to the stimulus resistor (4) of the bimetal element (3) and to the electrical ignition device (8) is interrupted and which can only be switched on again by manual operation. 2. Device according to claim 1, characterized in that that the actuator responsive to the flame formation is a helical is wound bimetal element (9). 3. Device according to claim 1 and 2, characterized characterized in that the actuator responsive to the formation of a flame Photo cell (15) which controls an electromagnet (13) (Fig.4). 4. Device according to claim 1 to 3, characterized in that the thermostat operated switch (7) an additional heating resistor (11) for the bimetal element (3) with a series switch (10) is connected in parallel with the Switch (1) of the fuel feed device (2) is operated. Considered publications: German Patent Specifications No. 457 496, 692 910, 895 360: USA.-Patent Specifications No. 2 077 402, 2 221 164.