JP3185504B2 - Combustion control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion control device.
More specifically, the present invention relates to a combustion control device used in a forced supply / exhaust type combustion device having a combustion fan.

[0002]

2. Description of the Related Art In a conventional forced-supply / exhaust water heater, the number of revolutions of a combustion fan is set to correspond linearly to the combustion amount of fuel gas (that is, proportional valve current). For example, the fan rotation speed of the combustion fan is detected by a fan rotation speed detector, and the fan rotation speed is determined according to the combustion amount so that the fan rotation speed is on a constant combustion amount-fan rotation speed characteristic function as shown in FIG. The number was feedback controlled. Accordingly, if the combustion amount of the fuel gas is the same regardless of the situation of the combustion apparatus, the fan speed is controlled to follow a uniquely determined target speed.

[0003]

However, according to such a control method, when the exhaust port of the combustion equipment is temporarily blocked or a disturbance such as a headwind occurs, the supply / exhaust balance is lost. However, the optimum air-fuel ratio cannot be obtained, and the combustion state changes. In addition, for example, the resistance of the air supply / exhaust passage increases due to clogging of the fins of the heat exchanger or filter clogging of the air supply unit, and dust adheres to the blades of the fan, causing aging and causing a substantial reduction in the air flow. Even in the case of a decrease, an optimum air-fuel ratio with respect to the combustion amount could not be obtained, and incomplete combustion was easily caused.

[0004] For example, when the filter clogs the air supply section of the combustion equipment due to the headwind, the load on the combustion fan is reduced, and the fan speed temporarily increases. However, since the fan speed is immediately feedback-controlled so as to be equal to the fan speed determined by the combustion amount, the amount of air supplied to the combustion unit by the combustion fan is further insufficient, and the air-fuel ratio is deteriorated. .

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned drawbacks of the prior art, and has as its object to always maintain a good combustion state even with temporary disturbance or aging. It is an object of the present invention to provide a combustion control device that can perform the combustion control.

A combustion control device according to the present invention includes a combustion fan for supplying combustion air, a detector for detecting a driving current or a driving voltage of the combustion fan, and a detector for detecting a rotation speed of the combustion fan. And the amount of combustion
A fan control unit that controls the fan speed in accordance with the combustion amount based on the relationship between the fan current and the drive current or the drive voltage. fan speed by controlling the fan speed to be equal to the value, comparing the fan speed of the normal corresponding to the predetermined value of fan speed detection value and the driving current or the driving voltage at that time
Is calculated, and the relationship between the amount of combustion and the fan speed is corrected using the correction coefficient .

In the combustion control device of the present invention, the fan speed is controlled in accordance with the combustion amount based on the relationship between the combustion amount of the combustion section and the fan speed. It can be directly obtained in correspondence, and the control process of the fan speed can be simplified. Further, in this combustion control device, at the start of the operation, the fan rotation speed is controlled so that the detected value of the drive current or the drive voltage becomes equal to a predetermined value of the drive current or the drive voltage. By comparing the detected value of the rotation speed with the normal fan rotation speed corresponding to the predetermined value of the drive current or the drive voltage (that is, the fan rotation speed when there is no disturbance or aging rate), the fan rotation speed can be calculated. Since the correction coefficient is calculated and the fluctuation of the fan rotation speed due to disturbance or aging is corrected using the correction coefficient, the correction coefficient of the fan rotation speed is calculated based on the predetermined relationship between the combustion amount and the fan rotation speed. By calculating by calculation, the fan rotation speed can be finely corrected (for example, a graph representing the relationship between the combustion amount and the fan rotation speed is shifted or the inclination is changed). To correct or.). In addition, since at least one basic relationship between the combustion amount and the fan speed need only be given, it is possible to reduce the amount of memory for storing the relationship between the combustion amount and the fan speed. it can.

[0008]

FIG. 1 is a schematic diagram showing a water heater 1 provided with a combustion control device according to one embodiment of the present invention. A heat exchanger 4 for heating water flowing through the hot water supply pipe 3 is provided in the can body 2.
And a gas burner 5, and the gas burner 5 is arranged below the heat exchanger 4. An exhaust port 6 is opened on the upper surface of the can 2, and a combustion fan 8 is provided on an air supply port 7 on the lower surface. Thus, combustion air is forcibly supplied to the burning gas burner 5 by the combustion fan 8, and the gas is burned at an optimum air-fuel ratio. In addition, hot water supply piping 3
Is connected to the hot water supply control unit 10, and when the hot water supply control unit 10 determines at the start of hot water supply that the incoming water flow rate Q is equal to or more than the minimum operating flow rate (MOQ) (hereinafter referred to as MOQ on). Then, a signal notifying that the MOQ is ON is output from hot water supply control section 10 to fan control section 11. A gas proportional valve 13 is provided in a gas supply pipe 12 that supplies gas to the gas burner 5, and the hot water supply control unit 10 adjusts a combustion amount W of the gas burner 5 by controlling an opening degree of the gas proportional valve 13. Hot water supply control unit 10
A signal indicating the combustion amount W of the gas burner 5 is output to the fan control unit 11 from. The fan rotation speed R of the combustion fan 8 is controlled by the fan control unit 11 by changing the fan drive current I supplied to the DC motor 14, and the fan rotation speed R and the fan drive current I are respectively detected by the fan rotation speed detection unit. 15 and the fan drive current detector 16, and each detection signal is input to the fan controller 11. Therefore, the fan control unit 11 performs feedback control of the fan rotation speed R of the combustion fan 8 so as to obtain a desired fan rotation speed corresponding to the combustion amount W while detecting the fan rotation speed R. A characteristic function F (W) for determining the fan rotation speed R with respect to the combustion amount W is determined so that an optimum air-fuel ratio can be obtained without disturbance, aging, and the like. 11 is stored. This characteristic function F (W) can be represented, for example, as a function R = F (W) indicated by a solid line in FIG.

FIG. 3 is a flow chart for explaining the processing procedure of the fan control section 11 having a built-in microcomputer. Hereinafter, the operation at the time of starting the operation of the combustion equipment will be described according to this flowchart. First, when the water in the hot water supply pipe 3 is opened and water starts flowing in the hot water supply pipe 3, the flow sensor 9 detects the incoming water flow rate Q and waits until the MOQ is turned on (S21). When the MOQ is turned on, a pre-purge process (S22) is entered, the fan speed R is controlled to a predetermined initial value Rpo (S23), and the fan drive current detector 16 drives the fan while keeping the fan speed R at Rpo. The current I is measured (S24). Then, whether the measured fan driving current I _DC is included within a predetermined range including a predetermined initial set value I _DC 0, i.e. in the range of _{I DC0 -β <I DC <I} DC0 + α ... (1) A determination is made (S25).
This initial setting value I _DC0 is the initial setting value Rpo of the fan rotation speed.
In the case where the fan rotation speed R is kept at Rpo, the fan drive current I is equal to the initial set value I _DC0 if the water heater 1 is in a normal state without disturbance or aging. Become. Therefore, if the measured value I _DC of the fan drive current is within the range represented by the above equation (1), it is determined that disturbance and aging are sufficiently small, and the gas burner 5 is ignited (S
31) After confirming the ignition (S32), the process proceeds to the steady combustion control (S33). In this case, since the characteristic function that determines the fan rotation speed according to the combustion amount has not been corrected, the fan rotation speed R is controlled using the original characteristic function R = F (W) shown by the solid line in FIG. Is done.

[0010] In contrast, in a case where the fan driving current I _DC at the time of keeping the fan speed R in Rpo is out of the range of the expression (1) (S25), disturbances and aging and the like is increased Is determined, and the correction operation of the characteristic function is executed. That is, the fan drive current I is equal to the initial set value I.
_The fan speed R is controlled to be equal to _DC0 (S2
6, S27), the fan rotation speed Ra when the fan drive current I becomes equal to the initial set value I _DC0 is measured (S2).
8). Next, a correction coefficient A = Ra-Rpo for obtaining the target rotation speed is determined from the initial setting value Rpo of the fan rotation speed and the measured value Ra of the fan rotation speed (S29). Then
The original characteristic function R = F (W) is corrected using the correction coefficient A, and a corrected characteristic function R = F (W) + A (2) is obtained (S30). Thereafter, the gas burner 5 is ignited (S
31) After confirming the ignition (S32), the process proceeds to the steady combustion control (S33). In this case, the fan speed R is controlled by the corrected characteristic function R = F (W) + A.

The determination as to whether or not disturbance or aging has occurred (S25) is performed without giving a range of determination.
I _DC = I _DC0 may be used instead of the above equation (1). Further, the correction coefficient B is expressed as B = R in the form of a ratio.
a / Rpo, and the characteristic function may be corrected by R = BF (W).

FIG. 4 is a diagram for explaining the reason for correcting the characteristic function as described above. FIG. 4 (a) shows the change in the fan rotation speed R, and FIG. 4 (b) shows the fan drive current I. FIG. 4C shows a change in the air-fuel ratio.
Before time t1, the combustion fan 8 operates at a fan rotation speed R = R
It is assumed that the hot-water supply device 1 was rotating at po and was burning at the optimum air-fuel ratio, but the air supply unit was suddenly closed at time t1 and the amount of air supplied to the inside of the hot-water supply device 1 was reduced. Further, it is assumed that the combustion amount W does not change. In this case, the combustion fan 8
4A, the fan rotation speed R increases from Rpo as shown by the solid line in FIG. 4A (time t1). If the characteristic function R = F (W) for controlling the fan speed R is not corrected, the combustion fan 8
As shown in FIG. 4 (b), the fan drive current I is reduced (time t2) because the rotation speed is controlled so as to be a constant rotation speed Rpo corresponding to the combustion amount W according to FIG.
As shown by the broken line in (a), the fan speed R is stabilized again at Rpo (time t3). At the same time, the rotation speed Rpo when the air supply is blocked and the fan rotation speed R is normal.
As a result, the combustion air becomes insufficient, and the air-fuel ratio becomes poor as shown by the broken line in FIG. 4C, resulting in incomplete combustion.

On the other hand, according to the combustion control device of the present invention, the fan drive current I is kept at a predetermined value I _DC0 at the start of operation, and the fan speed R is measured. As shown by the solid line in FIG. 4A, if the fan rotation speed R is larger than the normal fan rotation speed Rpo corresponding to the fan drive current I = I _DC0 (time t2), the fan rotation speed at that time Ra is measured, and the characteristic function is corrected using the correction coefficient A or B according to the equation (1) or (2). As a result, the characteristic function is corrected as shown by the one-dot chain line in FIG. 2, and becomes a characteristic function having a larger fan rotation speed R than the original characteristic function R = F (W) shown by the solid line. When steady combustion control is performed using this characteristic function R = F (W) + A [or R = BF (W)], the fan rotation speed R becomes Rpo as shown by the solid line in FIG. 4 (after time t2), the fan drive current I is also maintained at the current value I _DC0 without being reduced as shown by the solid line in FIG.
The air-fuel ratio is also maintained at the ideal air-fuel ratio as shown by the solid line in (c) (or the fluctuation from the ideal air-fuel ratio is reduced). Therefore, according to the combustion control device of the present invention, even if aging occurs or disturbance that changes gradually compared to one hot water supply operation time occurs, the characteristic function is corrected each time hot water supply is started. By doing so, the water heater 1 can be burned at an ideal air-fuel ratio.

In the above embodiment, when the fan drive current is made equal to a predetermined value (initial setting value), the ratio between the detected value of the fan rotation speed and the fan rotation speed corresponding to the predetermined value of the fan drive current is determined. The characteristic function was corrected.
When the fan drive voltage is equal to a predetermined value (initial setting value), the characteristic function may be corrected by the ratio between the detected value of the fan rotation speed and the fan rotation speed corresponding to the predetermined value of the fan drive voltage. Absent.

[0015]

According to the present invention, a change in the fan rotation speed due to disturbance or aging is evaluated and fed back to a function for controlling the fan rotation speed. Since the correction can be made, even if there is aging or disturbance of the combustion equipment, the combustion fan can be rotated at a fan speed corresponding to the change, and the combustion equipment can be burned at an appropriate air-fuel ratio.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing a hot water supply device provided with a combustion control device according to one embodiment of the present invention.

FIG. 2 is a diagram showing a characteristic function that determines a relationship between a combustion amount and a fan speed.

FIG. 3 is a flowchart illustrating a combustion control method according to the first embodiment.

4 (a), (b), and (c) are fan rotation speeds, respectively.
It is a figure showing change of a fan drive current and an air-fuel ratio.

FIG. 5 is a diagram showing an example of a characteristic function for controlling a fan speed in a conventional combustion control method.

[Explanation of symbols]

 5 Gas Burner 8 Combustion Fan 11 Fan Controller 13 Gas Proportional Valve 14 DC Motor 15 Fan Rotation Detector 16 Fan Drive Current Detector

────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Hideo Ueda No. 32, Akashi-cho, Chuo-ku, Kobe-shi, Hyogo Pref. (JP, A) Hikaru Heihei 3-87045 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) F23N 3/08

Claims (1)

(57) [Claims] 1. A combustion fan for supplying combustion air, a detector for detecting a drive current or a drive voltage of the combustion fan, a detector for detecting a rotation speed of the combustion fan, and a combustion unit for combustion. A fan control unit that controls the fan speed in accordance with the amount of combustion based on the relationship between the amount and the fan speed. At the start of operation, the detected value of the drive current or drive voltage is The fan speed is controlled so as to be equal to a predetermined value of the drive current or the drive voltage, and the detected value of the fan speed at that time is compared with the normal fan speed corresponding to the predetermined value of the drive current or the drive voltage. To calculate the correction coefficient for the fan speed, and calculate the correction coefficient
Combustion control apparatus being characterized in that so as to correct the relationship between the fan rotation speed for the combustion amount used.