KR910002880Y1 - Combustion sefaty device for gas apparatus - Google Patents

Abstract

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Description

Combustion safety device of gas appliance

1 is a side cross-sectional view of one embodiment of the present invention.

2 is a circuit configuration of the cross-sectional view taken along the line II-II of FIG.

3 is a diagram showing the change characteristic between the output of the first flame sensor and the fan speed.

4 is a graph showing the change in output with respect to the oxygen concentration in the air.

5 is an enlarged cross-sectional front view of the main portion of the modified example of the burner section.

6 is a plan view thereof.

7 is a cross-sectional view of another alternative embodiment of the burner portion.

8 is a diagram showing an example of a change in output with respect to the oxygen concentration in the conventional air.

* Explanation of symbols for main parts of the drawings

2: main burner 3: secondary burner

5: blower 6: first flame sensor

7 second flame sensor 8 comparator

9 gas supply unit 10 solenoid valve

The present invention relates to a combustion safety device for a gas appliance using a primary burner burner as the main burner.

Conventionally, as a combustion safety device for preventing oxygen deficiency, a thermocouple is installed in a burner, and the solenoid valve installed in the gas supply path is kept open by the output of the thermocouple. When oxygen is depleted, the flame lift is lifted from the thermocouple. It is already known to stop the combustion by closing the solenoid valve when the output decreases due to the deviation. However, as a gas mechanism using the primary air combustion burner, a blower forcibly supplying primary air to the burner is installed. In the case of burning by setting the excess air ratio (supply air / theoretical air amount) to 1.0 or more, since the combustion is always performed in the excess air state, even if the exhaustion is exhausted, normal combustion occurs despite the fact that the thermocouple is installed in the burner. When it is deficient, its output does not decrease so much to detect oxygen depleted combustion. Since the gas is difficult, in such a gas mechanism, a sub-burner such as Bunsen-type which is easy to cause a flame change when oxygen is deficient is provided, and the solenoid valve is opened and closed by the output of the thermocouple provided in the sub-burner. In this case, the output change characteristic of the thermocouple with respect to the change in the oxygen concentration in the air depends on the type of gas used, and even if the gas belongs to the same type, the Japanese Gas Appliance Inspection Association prescribes for each type of gas. Each test gas of 1 gas (gas to measure redness, soot generation, and CO concentration), 2 gas (gas to test flammability) and 3 gas (gas to test lift and blow off) Different change characteristics are shown.

FIG. 8 shows 1 gas (CH ₄ 85% -C ₃ H ₈ 15%), 2 gas (H ₂ 30% -CH ₄ 55% -C ₃ H ₈ 15%), 3 gas specified for the gas type 13A The change in the output of the thermocouple in each test of (CH ₄ 98% -N ₂ 2%) is indicated by the line l for 1 gas, the line m for 2 gas, and the line n for 3 gas. The theoretical air amount (air amount / gas amount) is 11.72, 2 gas is 9.533, 3 gas is 9.394, and the calorific value per unit volume increases in the order of 3 gas <2 gas <1 gas, and the output is correspondingly 3 gas <2 gas <1 gas as a whole.

Therefore, if the reference value S for thermocouple output is set so that combustion stops when oxygen concentration in the air becomes less than 18%, for example, when using one gas, the oxygen concentration in the air is 18% for 2 gas and 3 gas. Even at the relatively high level, the output of the thermocouple falls below the reference value S, and combustion is unnecessarily stopped.

In this case, the reference value may be adjusted to stop the combustion at the same oxygen concentration, but the types of gas actually supplied to the home are divided into a relatively wide range of components including the component differences corresponding to these test gases. It is practically impossible to adjust the reference difference in response to a change in the output characteristics of the thermocouple according to the component difference of the same gas type.

Here, the output of the thermocouple installed in the burner of the first primary air combustion type does not change so much even if the oxygen concentration in the air is changed as described above, and is expected to increase in the order of 3 gas <2 gas <1 gas, so this output Is used as a reference value, that is, the output of the first thermocouple installed in the main burner and the output of the second thermocouple installed in the secondary burner are compared with a comparator. It is conceivable that the combustion be closed so that combustion is stopped at the same oxygen concentration in any test.

However, since the theoretical air volume for each of 1 gas, 2 gas, and 3 gas is different as described above, if the number of revolutions of the blower is not changed according to each test gas, the excess air ratio is changed and the combustion state of the main burner is unstable. In addition, there is a problem that the output of the first thermocouple does not increase or decrease as scheduled according to each test gas.

In order to solve the above problems, the present invention automatically controls the blower's rotational speed so as to obtain a constant air excess rate regardless of the gas component difference, and the gas from the thermocouple and other flame sensors installed in the main burner. It is an object of the present invention to provide a device capable of obtaining a stable output corresponding to a component difference and using this as a reference value so that combustion can always be stopped at a constant oxygen concentration even when a gas component is changed.

In order to achieve the above object, the present invention includes a blower forcibly supplying primary air to the main burner, and the rotational speed of the blower is controlled to increase or decrease according to a predetermined proportional characteristic in response to the output of the first flame sensor. In one gas appliance, there is provided a primary air combustion main burner in which gas is supplied through a solenoid valve installed in a gas supply passage, and a secondary burner in which a flame is easily changed in case of oxygen deficiency. A first flame sensor is provided, and the sub-burner is provided with a thermocouple or a second flame sensor to control the opening and closing of the solenoid valve by the output from the comparator comparing the output from both flame sensors. .

It will be described below with reference to the drawings of the subject innovation.

1 and 2 are one embodiment of the present invention.

(1) in the figure is a heater main body having a rear inlet (1a) and a front warm air blower (1b), shown in the figure are flames when oxygen deficiency and the primary burner (2) of the primary air combustion type are in the main body. The secondary burner (3) and the blower (5) of the built-in combustion chamber (4) constituted by this changeable Bunsen burner are accommodated, and the indoor air is sucked from the inlet (1a) in accordance with the rotation of the blower (5). The combustion heat of the main burner 2 is sucked from the combustion exhaust port 4a in the upper part of (4), and both are mixed and ejected into the room through the ejection port 1b. In this case, the suction force of the blower 5 acts in the combustion chamber 4, which acts inside of it through the flame hole 2a of the main burner 2, and the primary air is forced from the mixing pipe 2b. Aspirated into the honorer 2, the primary air amount is increased in accordance with the rotation speed of the blower (5).

6 is a first flame sensor made of a thermocouple provided near the flame hole 2a of the main burner 2, and 7 is a thermocouple provided near the flame hole 3a of the secondary burner 3. The second flame sensor (8) made up is a comparator for performing current-voltage conversion and amplification on the outputs from both the flame sensors (6) and (7), respectively, and comparing the outputs from the comparator (8). Therefore, the solenoid valve 10 provided in the gas supply path 9 was made to control opening and closing.

According to the present invention, the number of revolutions of the blower 5 is controlled in accordance with a predetermined proportional characteristic in response to the output of the first flame sensor 6, which will be described in detail. From the rotational speed command circuit 12 and the rotational detection pick-up coil 13 of the blower 5, which generate a rotational command signal according to the output, for example, according to the proportional characteristic indicated by the V line in FIG. The rotation speed detection circuit 14 which generates a signal according to the actual rotation speed of the blower 5 by the output, and the automatic amplification circuit 15 which inputs the signals from both circuits 12 and 14 are provided. Then, the output of the automatic amplification circuit 15 causes the rotation control power transistor 16 of the drive motor 5a of the blower 5 to be operated so that the deviation of the signals from both circuits 12 and 14 can be achieved. The number of revolutions of the blower 5 is increased or decreased such that is 0, so that the number of revolutions of the blower 5 is the first flame In accordance with an output change of the stand (6) was adapted to be controlled by increasing or decreasing the proportion characteristic line V.

In addition, 11 in the figure is an opening / closing valve provided in the gas supply path 9.

Next, FIG. 3 shows that the supply rate is 3000 Kcal / h using the above three kinds of test gases as 13A, and the rotation speed of the blower 5 is set in a good combustion range (approximately 1.02 to the excess air ratio of the main burner 2). It is the result of measuring the output of the 1st flame sensor 6, changing within the range of 1.5), and h1 h2 and h3 show the change characteristic of 1 gas, 2 gas, and 3 gas, respectively.

As is evident in this figure, the rotation speed required for burning the gas under good conditions is high in order of 1 gas, 2 gas, and 3 gas. Therefore, in order to control the rotational speed of the blower 5 in proportion to the output of the first flame sensor 6, the proportional characteristic of each gas in the output region whose characteristic line V has a relatively small output change rate is h1 h2. , control can be ensured by setting to intersect with h3.

That is, when the gas supplied to the main burner 2 is changed from 3 gas to 1 gas, the output speed increases and the rotation speed increases along the line V, so the output is safe at the intersection Y1 of the line V and the line h1, and vice versa. When the gas is changed to 3 gas, the rotation speed decreases along the line V at the value Y1 due to the decrease of the output, and is stabilized at Y3 so that the flame does not go out of the wind or cause backfire.

Next, the operation by the apparatus of the present invention will be described for the case where three kinds of test gases of 13A are combusted.

When one gas is used, the output a1 of the first flame sensor 6 is stabilized at the intersection point Y1 of the line V and the line h1 as shown in FIG. 3, and the rotation speed of the blower 5 is also secured, so that good combustion continues. As a result, the output from the side of the first flame sensor 6 input to the comparator 8 is maintained at a substantially constant level, regardless of the oxygen concentration in the air, as shown by the line A1 shown in FIG.

When two gases are used, the output a2 of the first flame sensor 6 is stabilized at the intersection of the line V and the line h, and the rotation speed of the blower 5 is also stabilized, and the first flame sensor 6 input to the comparator 8 is used. The output on the) side is maintained at a constant level regardless of the oxygen concentration while lowering from line A1 to line A2.

Similarly, in the three gases, at the intersection point Y3 between the line V and the line h3, the output a3 of the first flame sensor 6 and the rotation speed of the blower 5 are stabilized, and thus the first flame sensor inputted to the comparator 8 ( 6) Maintain a constant level with the output on the side lowered again from line A2, as with line A3.

On the other hand, the change characteristic of the output from the side of the second flame sensor 7 installed near the sub burner 3 input to the comparator 8 is changed in accordance with the decrease in the oxygen concentration in the air as shown in FIG. It decreases like B1 (1 gas), line B2 (2 gas), and line B3 (3 gas), and the output level of each gas is equal to the output from the first flame sensor 6 of the main burner 2; As a result, it is lowered in the order of 1 gas> 2 gas> 3 gas.

When the output from the second flame sensor 7 side becomes lower than the output from the first flame sensor 6 side, the solenoid valve 10 is closed by the signal from the comparator 8.

Therefore, the oxygen concentration at which the solenoid valve 10 is closed is the concentration of X1, which is the intersection of both lines A1 and B1 for 1 gas, the concentration of X2 of the intersection X2 of both lines of A2 and B2 for 2 gases, and A3, for 3 gases. B3 is the concentration of the intersection X3 of the two lines, in this case, the height of each line of the reference value A1, A2, A3 changes according to the height difference between the angle lines of B1, B2, B3, so that the concentration of the intersection X1 and the intersection of X2 and X3 The concentrations are approximately the same, so that the solenoid valve 10 is closed at approximately the same oxygen concentration even if the components of the gas are different.

In the embodiment shown in Figs. 1 and 2, the secondary burner 3 is provided separately from the main burner 2, but the present invention is not limited to this, for example, as shown in Figs. The recessed part 18 is provided in part C of the surface of the burner plate 17 of the main burner 2, and the length of the flame hole 3a of (C) is different by this recessed part 18. By reducing the passage resistance of the flame hole 3a of (C) by making it shorter than the length of the flame hole 2a of (D), the load of the flame hole is increased and the flame hole 3a around the recessed portion 18 is increased. Part (19) having no teeth is provided so that the flame hole of (C) is independent from the other part (D), and this is the secondary burner (3) where the flame is liable to change in case of oxygen deficiency. The second frame sensor 7 may be brought closer to the upper side.

Moreover, the flame hole with a large load is formed even if the diameter of the flame hole 3a of this part is made slightly larger than the diameter of the other part D.

In addition, as shown in FIG. 7, a part of the main burner 2, for example, a sub-burner gas supply pipe 20 having a diameter of 8 mm is placed on the lower surface of the burner plate 17 of the main burner 2, for example, 5 mm. By arranging at intervals of a degree, a portion of the burner plate 17 having a gas enrichment portion slightly wider than the diameter of the supply pipe 20 is used as the secondary burner 3 which is liable to cause a flame change when oxygen is depleted. You may make the 2nd flame sensor 7 approach upper part of (3a).

Therefore, the operation effect of the sub-burner 3 in FIGS. 5-7 is no different from that of the embodiment of FIG. 1, FIG.

As such, according to the present invention, when the gas component is changed, the rotational speed of the blower which supplies primary air to the main burner by detecting the rising or falling of the output from the first flame sensor installed near the main burner has a predetermined proportional characteristic. It automatically maintains the excess air ratio within a certain good combustion range by controlling the increase and decrease automatically, and the output according to the gas component from the first flame sensor can be stabilized, and from the second flame sensor installed near the secondary burner The difference in output which follows the gas component is offset by the difference in output according to the gas component difference from the first flame sensor, so that even if the gas component is changed, combustion is always stopped at a constant oxygen concentration and the reliability of the apparatus is improved.

Claims (4)

A blower 5 is provided with a blower 5 forcibly supplying primary air to all primary air-burning main burners 2 through which the gas is supplied through the solenoid valve 10 installed in the gas supply path 9. In a gas appliance configured to increase or decrease the rotational speed of the blower 5 according to a predetermined proportional characteristic with respect to the output of the first flame sensor 6 installed close to 2), if oxygen is deficient, the lift of the flame is lifted. ), The output from the secondary burner (3), the second flame sensor (7) installed close to the secondary burner (3), and the first and second flame sensors (6), (7) And a comparator (8) for comparing and controlling the opening and closing of the solenoid valve (10) by an output from the comparator (8). 2. Combustion safety device for a gas appliance according to claim 1, characterized in that the secondary burner (3) is provided on the burner plate separately from the main burner (2). The combustion safety device of a gas appliance according to claim 1, wherein a recess (18) serving as a secondary burner is provided in a part (C) of the surface of the burner plate (17) of the main burner. The combustion safety device of a gas appliance according to claim 1, wherein a gas supply pipe (20) for the burner is provided at intervals on the lower surface of the burner plate (17) of the main burner to serve as a secondary burner.