JPH03181708A - Combustionair/fuel ratio control device for heating apparatus - Google Patents

Abstract

PURPOSE:To obtain optimum air/fuel ratio against changes in air density resulting from the elevation of installation location and changes in draft resistance without using any dumper by a method wherein a different linear function is obtained by each of adjusting volumes and a combustion air blower and a fuel supply pump are controlled based on the linear function. CONSTITUTION:A revolution number position within the range of small revolution numbers is set by a small revolution number adjusting volume 6, a revolution number position within the range of large revolution numbers is set by a large revolution number adjustment volume 7, the setting of each of the revolution number positions is changed by an air amount adjusting volume 8 and an oil amount position within the range of large oil amounts is set by a large oil amount adjusting volume 9. A linear function of air/fuel ratio is computed based on each of the set revolution number positions and each of the set oil amount positions and, based on the linear function, an air blower 2 and a fuel supply pump 3 are driven. This method permits the optimum air/fuel ratio to be obtained, even when draft resistance is changed.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a combustion air-fuel ratio control device for a heater that controls the air-fuel ratio, which is the ratio between the amount of air and the amount of oil.

(Conventional technology) Conventionally, heaters are equipped with a combustion blower that supplies combustion air to the burner and a fuel supply pump that supplies oil.The amount of air is controlled by a damper to maintain a constant air-fuel ratio. I have to.

However, in such a heater, the air density differs depending on where the heater is installed, that is, when it is installed in a lowland and when it is installed in a highland, so the amount of air changes. When dust adheres to a dust removal filter or the like, its ventilation resistance increases and the amount of air tends to decrease.

When such a situation occurs, the opening degree of the damper is finely adjusted to correct the amount of air and keep the air-fuel ratio constant.

(Problem to be Solved by the Invention) However, when the air-fuel ratio control is corrected using a damper in this way, even when the damper opening degree changes slightly, the amount of air changes greatly. The fine adjustment was extremely troublesome.

Further, the air amount may be appropriate during small combustion, but may be inadequate during large combustion, or may be in the opposite situation. In such cases, even if the damper opening is adjusted to correct the defective condition, the large or small combustion conditions that were previously appropriate often become defective, making it impossible to adjust the air-fuel ratio. also occurred.

SUMMARY OF THE INVENTION In view of the above-mentioned conventional problems, an object of the present invention is to provide a combustion air-fuel ratio control device for a heater that can reliably obtain a desired air-fuel ratio without using a damper.

(Means for Solving the Problems) In order to solve the above problems, the present invention provides a combustion air-fuel ratio of a heater that proportionally controls the amount of air by a combustion blower and the amount of oil by a fuel supply pump based on a linear function. The control device includes a small rotation speed adjustment volume that adjusts the rotation speed of the combustion blower in a small rotation speed range based on a plurality of rotation speed positions having different rotation speeds, and a rotation speed of the combustion blower in a large rotation speed range. a large rotational speed adjustment volume that adjusts the rotational speed based on a plurality of rotational speed positions having different rotational speeds, and each of the rotational speed positions set by the rotational speed volume is changed equally in the direction of increasing or decreasing the rotational speed of the combustion blower. and a large bending amount that adjusts the oil amount in the large oil amount range of the fuel supply pump based on a plurality of oil amount positions with different oil amounts. and a drive control means for driving the combustion blower and the fuel supply pump based on the linear function obtained by the calculation means. Features.

(Function) According to the present invention, the small rotation speed adjustment volume sets the rotation speed position in the small rotation speed range, the large rotation speed adjustment volume sets the rotation speed position in the large rotation speed range, and the air volume adjustment volume sets the rotation speed position in the large rotation speed range. The setting of the rotation speed position is changed, and the oil amount position in the large oil amount range is set by the large oil amount adjustment volume.

A linear function of the air-fuel ratio is calculated based on each set rotational speed position and oil amount position, and the combustion blower and fuel supply pump are driven based on this linear function.

This makes it possible to obtain the optimum air-fuel ratio even when ventilation resistance or the like changes.

In addition, as mentioned above, by changing each rotation speed position already set by each rotation speed volume with the air amount adjustment volume, the air amount can be constantly increased or decreased from the small rotation speed range to the large rotation speed range of the combustion blower. The air volume that has already been set can be easily changed.

(Embodiment) FIGS. 1 to 5 show an embodiment of the present invention, and FIG. 1 shows a semi-closed pot-type kerosene stove. In the figure, 1
is a semi-enclosed pot-type kerosene stove with a built-in pot burner (not shown). The stove 1 also has a built-in combustion blower 2 and an electromagnetic pump 3 driven by an AC power source as shown in FIG. 4. The combustion blower 2 supplies combustion air, and the electromagnetic pump 3 supplies combustion oil. Feed to pot burner. Furthermore, an operation panel 5 is provided on the front panel 4 of the stone 1.

FIG. 2 is an enlarged front view of this operation panel 5. As shown in FIG. The operation panel 5 has a small rotation speed control volume 6 on its negative side.
, large rotation speed adjustment volume 7, air volume adjustment volume 8
and large oil volume adjustment volumes 9 are arranged in the horizontal direction. Further, on the other side of the operation panel 5, a first display section 10 that displays the number of levels of the small rotation speed adjustment volume 6 and a second display section 11 that displays the number of levels of the large rotation speed adjustment volume 7 are provided.
, a third display section 12 that displays the number of levels of the air volume adjustment volume 8, and a fourth display section 13 that displays the number of levels of the large oil volume adjustment volume 9, and each display section 10-
13 are arranged sequentially from the end of the operation panel 5. Each of the display sections 10 to 13 is composed of a 7-segment LED, and each display section 10 to 13 displays the level number rlJ.
8" can be displayed. In addition, each adjustment volume 6 to 9 is a push button type volume and changes by 1 position each time it is pressed.
” is displayed repeatedly. Incidentally, reference numeral 14 is an oil amount adjustment knob that can be adjusted from small combustion to large combustion.

FIG. 3 is a graph showing the characteristics of the combustion blower 2 and the electromagnetic pump 3 which are adjusted by the A adjustment volumes 6 to 9. As shown in FIG. 3, the small rotation speed adjustment volume 6 adjusts the small rotation speed range of the combustion blower 2 to 1107 Orp.
Rotation speed position α ~ in 8 steps from to 156 orpm
θ can be Flu.

The large rotational speed adjustment volume 7 can adjust the large rotational speed range of the combustion blower 2 in eight steps from 1950 rpm to 2650 rpm at rotation speed positions a to h. The air volume adjustment volume 8 is set at each rotation speed position α to θ, which is set by the small rotation speed adjustment volume 6 and the large rotation speed adjustment volume 7.
A-h are a pair, and the rotation speed can be changed in equal positions in the direction of increase or decrease in the rotation speed, and can be adjusted in eight steps based on each rotation speed position α to θ of the small rotation speed adjustment volume 6. The large sake La adjustment volume 9 can adjust the oil amount position A-H in 8 steps from 16.7511z to 19.75tlz in the large oil amount range. Note that the rotation speed positions α to θ of the small rotation speed adjustment volume 6 are paired with the displays “1” to “8” on the first display section 10, that is, “α” and “
1"..."θ" corresponds to "8", and these positions α to θ are sequentially displayed as "1" to r8J. Similarly, the rotation speed positions a - h of the large rotation speed adjustment volume 7 are sequentially displayed as "1" to "8" on the second display section 11, and each position α of the air ff1M adjustment volume 8 is
~θ is sequentially displayed as "11" to "8" on the third display section 12, and the oil volume positions A-H of the large oil volume adjustment volume 9 are sequentially displayed as "1" to "8" on the fourth display section 13. be done.

Figure 4 shows a combustion blower 2, an electromagnetic pump 3, and each display section 10.
This is a block showing control circuits 1 to 13.

In the figure, reference numeral 15 is a CPU configured as a microcomputer, and each adjustment volume 6 to 9 is connected to an input terminal of this CPU 15. Each drive circuit 16. is connected to the output side of the CPU 15.
The display units 10 to 13 are connected via 17, 18, and 19, and the combustion blower 2 is connected via a drive circuit 20 and a rotation speed converter 21, and further, a drive circuit 22 and a frequency converter 23 are connected. An electromagnetic pump 3 is connected via.

FIG. 5 is a flowchart showing drive control of the combustion blower 2, the electromagnetic pump 3, and each of the display sections 10 to 13 by the CPU 15. That is, it is determined whether or not the small rotation speed adjustment volume 6 is set at which position among the rotation speed positions α to θ (81 to S8), and the level number corresponding to each set rotation speed position α to θ is determined. 1” to “8” are displayed on the first display unit 10 via the drive circuit 16 (S9 to 5).
16). Next, it is determined which position among the rotation speed positions a to h the large rotation speed adjustment volume 7 is set (317 to 524), and the level number "1" corresponding to each of the set rotation speed positions a to h is determined. ” ~ “8”
is displayed on the second display section 11 via the drive circuit 18 (8
25-532).

Furthermore, it is necessary to determine which position among the positions α to θ the air volume adjustment volume 8 is set to.83
3 to 540), the number of levels "1" to "8" corresponding to each of the set positions α to θ is transmitted to the third drive circuit 18.
It is displayed on the display unit 12 (841-548). Furthermore,
349 To judge whether the large oil amount adjustment volume 9 is set to which position among each oil amount position A-H.
- 556), the number of adjustment levels "1" to "8" corresponding to each of the set positions A-H is displayed on the fourth display section 13 via the drive circuit 19 (857-564).

In this way, when each position α to θ, ah, A to H is set, a linear function that displays the rotation speed of the combustion blower 2 and the frequency of the electromagnetic pump 3 is calculated (565), and this straight line A signal corresponding to the function is output to the rotation speed converter 21 via the drive circuit 20, and the combustion blower 2 is controlled to the set rotation speed (866). Further, a signal corresponding to this linear function is output to the frequency converter 23 via the drive circuit 22, and the electromagnetic pump 3 is controlled to a set frequency (S
67).

A specific example of the drive control as described above will be explained based on FIGS. 2 and 3. For example, the small rotation speed adjustment volume 6 sets the rotation speed position γ, the large rotation speed adjustment volume 7 sets the rotation speed position C, the air volume adjustment volume 8 sets the position γ, and the large oil volume adjustment volume 9 sets the oil volume position C. When set, each display section 10
.about.13 is displayed, and the linear function (I) shown by the solid line in FIG. 3 is obtained. In addition, each adjustment volume 6~
By changing the settings of 9, a wide variety of linear functions can be obtained.

Therefore, even if the stove 1 is installed at a high or low altitude and the air density changes, the ventilation resistance increases due to the adhesion of dust, or there is an error in the discharge amount of the electromagnetic pump 3, the optimum air condition will be maintained. The fuel ratio can be obtained.

In addition, as mentioned above, each adjustment volume 6 to
9, set the position ``γ'' of the air volume adjustment volume 8 to ``
δ”, the level number on the third display section 12 is “3”.
” changes to “4”, and the linear function (I) changes to the linear function (II
). That is, this air amount adjustment volume 8 is
The amount of air can be constantly increased or decreased from a small rotation speed range to a large rotation speed range of the combustion blower 2. Therefore, the user can easily adjust the air amount using the air amount adjusting volume 8 without adjusting other rotational speed adjusting volumes 6.7. In addition, in adjusting this air amount adjustment volume 8, the linear function (III) (
When the air amount cannot be adjusted by the air amount adjustment volume 8, such as when the air amount is not adjusted (mV), "0" is displayed on the third display section 12.

In the above embodiment, each adjustment volume 6 to 9 is set to eight positions, but the position is not limited to this.
5BOrpm, large rotation speed range from 195Orpm to 26
5Orpm, large oil volume range 16.7511z-19,75
11z, but it goes without saying that it may be changed depending on the model of the heater.

(Effects of the Invention) As explained above, according to the present invention, a linear function with a large number of scales can be obtained by each adjustment volume, and the combustion blower and fuel supply pump can be controlled based on this linear function. The optimum air-fuel ratio can be obtained without using a damper in response to changes in air density and changes in ventilation resistance due to the height of the air flow. Further, the air amount can be constantly increased or decreased from a low rotation speed range to a large rotation speed range of the combustion blower using the air amount adjustment volume, and the air amount can be easily adjusted.

[Brief explanation of drawings]

Figures 1 to 5 show one embodiment of the present invention; Figure 1 is a perspective view of a pot-type kerosene stove, Figure 2 is an enlarged front view of the operation panel, and Figure 3 is a combustion stove. FIG. 4 is a block diagram showing the control circuit for the combustion blower, electromagnetic pump, and each display section. FIG. 5 is a flowchart showing the drive control of the CPU. In the figure, 1... pot type kerosene stove, 2... combustion blower, 3... electromagnetic pump, 6... small rotation speed adjustment volume, 7... large rotation speed adjustment volume, 8...
Air volume adjustment volume, 9...Large oil volume adjustment volume, 15...CPU0

Claims (1)

[Scope of Claims] A combustion air-fuel ratio control device for a heater that proportionally controls the amount of air by a combustion blower and the amount of oil by a fuel supply pump based on a linear function, comprising: a small rotation of the combustion blower; a small rotation speed adjustment volume that adjusts the rotation speed in a large rotation speed range based on a plurality of rotation speed positions with different rotation speeds, and a small rotation speed adjustment volume that adjusts the rotation speed in a large rotation speed range of the combustion blower based on a plurality of rotation speed positions with different rotation speeds a large rotational speed adjustment volume to adjust the rotational speed; an air amount adjustment volume to equally change each rotational speed position set by the rotational speed volume in the direction of increasing or decreasing the rotational speed of the combustion blower; A large oil amount adjustment volume that adjusts the oil amount in the oil amount range based on multiple oil amount positions with different oil amounts, and the linear function is calculated based on each rotation speed position and oil amount position set by each of the adjustment volumes. 1. A combustion air-fuel ratio control device for a heater, comprising: a calculation means for calculating, and a drive control means for driving the combustion blower and the fuel supply pump based on the linear function determined by the calculation means.