DE102008057697A1 - Device for converting e.g. tile stove into electronically controlled combustion stove, has controller controlling motor using control algorithm so adjustment elements control combustion air quantity necessary for combustion - Google Patents

Abstract

The device has an electronic micro-controller (6) measuring carbon monoxide content in exhaust gas using a gas sensor (11). The controller measures exhaust gas temperature using a temperature sensor (10) and controls a servo motor (9) using a control algorithm so that adjustment elements of combustion air control combustion air quantity necessary for combustion with respect to efficiency and exhaust emission. The adjustment elements are covered by a housing (7), which is provided with an opening mechanism. An independent claim is also included for a method for converting a wood stove into an electronically controlled combustion stove.

Description

In Wood stoves of conventional design (tiled stoves, Stoves etc.), the burn-off by the supply of combustion air over an adjusting organ manually controlled. During the heating phase This adjusting must be repositioned constantly to avoid overheating or soot and CO formation. factors as the weather and quality of the fuel complicate a correct regulation.

The specified in claim 1 invention has set itself the task Wood stoves of different design as possible without major mechanical changes easy and cost-effective on electronically controlled, environmentally friendly Convert burnup. It should both low exhaust emissions as well as low heat losses can be achieved.

Under the patent number EP 0 604 388 A1 an invention is presented, which regulates the combustion air supply to an oven. The control has as input an oxygen sensor and a temperature sensor. The lambda probe causes a linear adjustment of the closure member so that the combustion gas contains only the lowest possible amount of oxygen. The temperature sensor closes the air supply as soon as a certain temperature is reached. According to the description of the invention, the air inlet openings of the closure member must be linearly increased or decreased in order to achieve optimum control.

These Invention is unsuitable for retrofitting most furnace systems, because only a few ovens equipped with a linear acting closure member and retrofitting is difficult and expensive. Execution with Lambda probe drives the costs in addition to the amount.

One essential error of the invention is the control over the lambda probe to the lowest possible amount of oxygen in the combustion gas. The burning of wood always requires an excess of oxygen. This surplus is highly dependent of the type of plant and the fuel and is between 1.4 and approx 3 ([1], page 31). Lambda probes deliver only very weak ones in this area Input signals as it develops for the automotive industry where values of lambda around the value one are needed. The probe input signals must therefore be extremely amplified which leads to large variations in the measured value.

A Implementation of the invention as described results in enhanced CO formation and is therefore harmful to the environment.

The in claim 1 listed invention circumvents the problem the inaccurate lambda control. As a basis, she has an intelligent Microcontroller control. This control captures over a temperature sensor, the exhaust gas temperature and a Gas sensor the CO concentration in the exhaust gas and controls over a control algorithm a servomotor and a coupled thereto Adjustment of the amount of combustion air, so a lowest possible carbon monoxide value in the exhaust gas at the fastest rate possible reduction of the exhaust gas temperature is achieved.

• – Flash Speicher zur Aufnahme des Programms mit dem Regelalgorithmus und der Parametrierung
• – EEROM Speicher zur permanenten Ablage der Parameter
• – digitale IO-Schnittstellen zur Ansteuerung des Stellmotors, zum Anschluss einer Tastatur und eines Displays
• – analoge Eingänge zur Erfassung von Temperatur und CO-Konzentration

The microcontroller offers all the features required by a controller:

• - Flash memory for recording the program with the control algorithm and the parameterization
• - EEROM memory for permanent storage of the parameters
• - digital IO interfaces for controlling the servomotor, for connecting a keyboard and a display
• - Analogue inputs for the detection of temperature and CO concentration

The Invention takes advantage of the fact that in the cheek phase a lot of combustion air for the pyrolysis (outgassing of the wood) is required and thereby very high exhaust gas temperatures (approx. 250 ° Celsius) while in the Ember phase of the furnace, the combustion air is completely throttled and the exhaust gas temperature falls to a minimum (<80 ° Celsius). The aim of the regulation described below is as possible fast, low-emission transition of the warm-up phase into To reach the glow phase and thus the exhaust gas losses as possible to keep low

Of the Microcontroller detects as input variables the Temperature and the CO value in the exhaust gas and provides as output a control value for the servomotor, the on adjoining adjusting mechanism adjusts the amount of combustion air. The temperature in the exhaust gas increases with increasing and decreasing with decreasing air supply.

The change the volume flow in the exhaust pipe also has a change the CO values result. Rising volume flows provide initially also for rising CO values, falling Volume flows initially cause a drop in the CO values to a minimum and then lead to a, through low-air combustion justified recovery. This Minimum of CO concentration that occurs during combustion depending on the combustion chamber temperature, the fuel and other factors, keeps setting is the task of the regulation.

After the ignition of the stove is first monitored the exhaust gas temperature. The adjusting member for the amount of combustion air is fully open. As soon as the temperature reaches a maximum value that can be parameterized in the controller, the controller is activated in the microcontroller. Initially, it limits the exhaust gas temperature to this maximum value, thus preventing emigration of the source of the fire to the chimney pipe. In the further course of the combustion, the exhaust gas setpoint temperature for this controller is newly determined from the temperature profile in the exhaust gas, a parameterizable temperature gradient (about 5 degrees / minute) and the trend in the CO content of the exhaust gas at intervals of three seconds. To determine the CO trend, the CO values are averaged over the same period. The minimum of these averages is stored and forms the reference for the evaluation of the trend: CO trend = CO mean - CO minimum

• → Reduktion der Solltemperatur über einen parametrierbaren Temperaturgradienten. (ca. 5 Grad/Minute)
• → CO-Minimum = CO-Mittelwert

gleichbleibender CO-Trend:
(1.03·CO-Minimum > CO-Mittelwert > CO Minimum)

• → Reduktion der Solltemperatur über den Temperaturgradienten. (CO-Mittelwerte im Bereich bis 3% oberhalb des Minimums liegen noch im Bereich der normalen Streuung)

fallende oder gleichbleibende Abgastemperatur und steigender CO-Trend:
(CO-Mittelwert > = 1.03·CO-Minimum)

• → Erhöhung der Solltemperatur auf einen Wert zwei Grad größer als die aktuelle Abgastemperatur

steigende Abgastemperatur und steigender CO-Trend:

• → CO-Minimum wird auf einen Höchstwert initialisiert

The trend of the CO averages and the change in the exhaust temperature have the following effects on the setpoint temperature:
falling CO trend:
(CO mean <CO minimum)

• → Reduction of the setpoint temperature via a parameterizable temperature gradient. (about 5 degrees / minute)
• → CO minimum = CO mean value

Consistent CO trend:
(1.03 · CO minimum> CO mean> CO minimum)

• → Reduction of the setpoint temperature over the temperature gradient. (CO mean values in the range up to 3% above the minimum are still within the range of normal scattering)

falling or constant exhaust gas temperature and increasing CO trend:
(CO mean> = 1.03 · CO minimum)

• → Increasing the setpoint temperature to a value two degrees higher than the current exhaust gas temperature

rising exhaust gas temperature and rising CO trend:

• → CO minimum is initialized to a maximum value

Out the setpoint-actual comparison of the exhaust gas temperatures determined by the microcontroller a PID controller once a second a manipulated value for the Servo motor so that the amount of combustion air through the adjusting is set so that the exhaust gas temperature as possible exactly the set temperature corresponds.

The Regulation causes a very efficient reduction of the exhaust gas temperature along a minimum of CO concentration, thus ensuring an optimized efficiency with low pollutant emissions.

The Control over the exhaust gas temperature has the advantage that the temperature detection very accurate and very fast to realize is and thus a very precise supply of combustion air guaranteed. The evaluation of a relative CO value over a fixed time interval saves the time-consuming calibration of the CO probe. Furthermore, factors such as pollution and aging of the probe not the influence on the control behavior, as with a control absolute CO values would be the case.

One Feature of the invention is the control of the adjusting over a servo. This drive allows the approach of absolute positions and is therefore particularly suitable for a controller operation.

at the servo can, for example, a known from the model standard servo be used. This servo is inexpensive, robust and positioning accuracy. It is coupled to the microcontroller control and can be within a range of about 0-90 degrees be positioned. The microcontroller software allows learning programming the servomotor with the adjusting member coupled thereto for the positions 'fully open' and 'fully closed'. During the combustion control, the air supply is then almost steplessly regulated between the stored full rashes. The control technology adaptation to different designs for the adjustment is guaranteed.

The mechanical adaptation to different designs is over two variants possible. Either will The servo is adapted directly to an existing adjustment or is housed in a housing that has an existing one Adjusting organ completely covered and the function of the original Adjusting organ takes over.

A particular feature of the invention is the automatic detection of the opening of the combustion chamber door ( 1 ) during the annealing phase. For this, the course of the CO measured value is evaluated over the period of one second. A percentage increase greater than ten percent is interpreted as door open and a cheer cycle is initiated.

In This Anfeuerzyklus the adjusting is initially as long fully open until a configurable exhaust gas temperature rise is reached. Thereafter, it will return to the exhaust control described above switched

The adjustment can be fully opened by the operator at any time at the touch of a button on the control unit or fully closed. The manual Close also terminates the start-up cycle (eg door opening without readjustment).

The Invention allows the burn-up repeatable accurate, largely regardless of weather conditions, fluctuations in fuel quality or design of the adjusting member for the combustion air supply to regulate.

she ensures an environmentally friendly and economical at all stages Burnup and is extremely user friendly.

she is simple and without major mechanical changes cost-effective to adapt to different furnace types.

One Embodiment of the invention is in the drawing shown schematically and is described in more detail below:

1 shows the basic structure of a wood stove. About the combustion chamber door ( 1 ) the stove is stoked. The lower door ( 2 ), behind which the ash drawer is located, also contains the opening for the air supply ( 3 ) with the air slide ( 4 ) over which the burnup is controlled manually. The exhaust pipe ( 5 ) introduces the combustion gases into the chimney.

2 , shows the same oven with the extensions for electronically controlled burnup.

The opening for the air supply of the stove ( 3 ) comes complete with a nearly airtight closing housing ( 7 ) obscured. This is fixed with a temperature-resistant adhesive or inside glued, heat-resistant magnets (hard ferrites). It has at the top a rotatably mounted flap ( 8th ), via a linkage with the servomotor ( 9 ) is connected in its interior.

In the exhaust pipe ( 5 ) protrudes the sensor unit with the temperature sensor ( 10 ) and the CO sensor ( 11 ).

The microcontroller control ( 6 ) is outside the oven. It includes a display for parameterization and visualization as well as a keyboard for operation.

she is via measuring and control lines with the sensors and connected to the servomotor.

The Installation of the device to an existing furnace system is possible in the shortest possible time. It only requires a small hole in the exhaust pipe for receiving the sensor unit.

The Housing with the servomotor becomes magnetic or with temperature-resistant Glue positioned over the air slider. Finally become the sensors and the servomotor with the microcontroller control electrically connected.

The adaptation to another design of the furnace is z. B. possible as follows:
Mechanically:
on the ash door is a 90 degree angled pin, which is screwed into the internal thread of a round magnet made of hard ferrite, fixed approximately in the center of the door. The pin is parallel to the axis of rotation of the door upwards.

In this pin is a sitting on a rod ball joint hung almost free of play. The other side of the linkage we with the mechanical connection of an externally fixed servo connected. The servo is placed so that it is the adjusting member Close completely and open as much as possible can.

Control technology:
Via a menu item of the microcontroller control the mode, learning programming adjustment 'is activated. The adjusting element can then be moved to the 'closed' and 'open' positions via the keyboard. Both positions are permanently stored in the control as end positions for the controller described above.

References:

• [1] Center for Biomass Technology (Denmark) - Theory of wood burning, Internet: http://www.videncenter.dk/groenne%20trae%20haefte/Groen_Tysk/traeDE06.pdf

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 0604388 A1 [0003]

Claims (4)

Device and method for converting wood-burning ovens to electronically controlled burn-up, characterized in that an electronic control system ( 6 ) via a gas sensor ( 11 ) the carbon monoxide content in the exhaust gas and via a temperature sensor ( 10 ) measures the exhaust gas temperature and via a control algorithm a servomotor ( 9 ) is controlled so that an adjusting mechanism for the combustion air coupled thereto ( 8th ) optimized for the combustion amount of combustion air in terms of efficiency and exhaust emission Device and method according to claim 1, characterized in that an adjusting device present on the furnace ( 3 . 4 ) for controlling the combustion air with a housing ( 7 ), which has an adjustable opening mechanism ( 8th ) with a servomotor ( 9 ) and thus assumes the function of the original adjustment Device and method according to claim 1, characterized in that an adjusting device present on the furnace ( 2 . 4 ) is adapted to control the combustion air to a servomotor Apparatus and method according to claim 2 and 3 characterized characterized in that the servomotor as a servo, as it for example used in model making, is designed and starting from Absolute values allowed