KR0145172B1 - Blower motor controller of hot air type heater - Google Patents

Abstract

The present invention relates to a blower motor control device that controls the number of revolutions of a blower motor used for blowing air for a hot air heater, and the like. The rotation speed is controlled by alternately executing 1 / n and 1 / (n + 1) as the ratio of the cycle cut of the AC voltage, all of which are programs of a microcomputer having a counter that counts n. Controlled by

By using such a device, the speed change in the low speed region of the blower motor is smoothed and there is no feeling of cold wind or the combustion state deteriorated temporarily.

Description

Blowing motor control device such as hot air heater

1 is a circuit diagram constituting a blower motor control apparatus such as a warm air heater according to the present invention.

2 is a flowchart showing the operation of the first embodiment of the blower motor control apparatus according to the present invention.

3 is a flowchart showing the operation of the second embodiment of the blower motor control apparatus according to the present invention.

4 is a timing diagram of a voltage waveform for explaining the operation of Embodiment 1 of the blower motor control apparatus according to the present invention.

5 is a timing diagram of a voltage waveform for explaining the operation of the second embodiment of the blower motor control apparatus according to the present invention.

6 is a timing chart of the operation waveform of the third embodiment of the blower motor control apparatus according to the present invention.

7 is a timing diagram of voltage waveforms for explaining the operation of the conventional blower motor control apparatus.

* Explanation of symbols for main parts of the drawings

2: zero cross pulse generating circuit 3: microcomputer

4: Calling circuit 6: Blowing motor

The present invention relates to a blower motor control apparatus for controlling the number of revolutions of the blower motor used for blowing in a hot air heater or the like.

2. Description of the Related Art A cycle cut method is conventionally employed as a rotation speed control method of a blower motor such as a warm air heater.

7 is a timing diagram of the voltage waveform of the blower motor control device disclosed in Japanese Patent Laid-Open No. 58-58894, where c is an output signal obtained by using a square wave oscillator circuit, and d is applied to a blower motor. Voltage waveform.

In general, in a warm air heater or the like which burns kerosene or the like and uses the combustion heat to heat a room, the calorific value is controlled in multiple stages, and when the room temperature approaches the set temperature, the calorific value is gradually reduced to control the room temperature to be kept constant. At this time, the set speed of the blower motor is changed according to the amount of heat generated. For example, when the amount of generated heat is weak, the blower motor is lowered so that the temperature of the warm air is lowered to prevent cold air. Drive. In addition, since the wind sent by the blower motor also acts as secondary air during partial combustion, it is necessary to set the rotation speed of the blower motor in detail according to the combustion amount.

Conventional rotation control of a blower motor, such as a warm air heater, by controlling the firing of the thyristors at the point where the AC voltage waveform intersects 0V and at the same time the thyristor that controls the power supply to the blower motor The power control to the blower motor was performed by subtracting one cycle at a specific time interval (n cycles) to perform power control. The rotation speed control was performed in multiple stages by changing the time interval (n value). . Here, n is the frequency of the AC voltage supplied to the blowing motor during the high speed region operation of the blowing motor, and depends on the rated frequency of the blowing motor.

Since the conventional rotational speed control method of a blower motor such as a warm air heater is the same as described above, when the value of n decreases, the rotational speed changes significantly step by step only when n is changed by one cycle. The controllability in the low speed range is poor because it cannot be set. For this reason, for example, it is difficult to set the rotational speed of the optimal blower motor for the combustion amount at the time of weak combustion by the value of the constant n, and it is difficult to set the optimal blowing amount, so that there is a feeling of cold wind or bad combustion condition. there was.

In addition, when the combustion amount is changed, the number of revolutions of the blower motor is also changed one by one. However, when the combustion amount decreases and the value of n decreases, there is a problem that the combustion state worsens in that the value of n changes. .

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and to obtain a blower motor control device such as a warm air heater, which can obtain an optimal blow amount according to the combustion amount by improving the controllability in the low speed region of the blower motor.

A blower motor control apparatus such as a warm air heater according to the present invention has a zero-cross pulse generation request that generates a pulse at the point where the AC power supply voltage crosses 0V, and the cycle of the AC power supply voltage according to the pulse from the zero-cross pulse generation circuit. And a microcomputer for outputting an oscillation output signal subtracting one cycle from the cycle counted by the counter, and a thyristor firing circuit connected in series with the blower motor, wherein the microcomputer has 1 / N and 1; The voltage of the cycle cut of (N + 1) is alternately applied to the blower motor to control the blower motor.

The present invention also has a second and a third counter for counting the number of cycle cuts of 1 / N and cycle cuts of 1 / (N + 1) in the microcomputer, and these second and third counters are predetermined. Each time the count is counted, the cycle cut is changed.

In addition, the present invention is to change the set speed of the blower motor, the microcomputer is to shift to the set speed while gradually changing the value of the second and third counter.

A blower motor control apparatus such as a warm air heater in the present invention alternately converts the voltage of a cycle cut of 1 / n and the voltage of a cycle cut of 1 / (n + 1) when the rotation speed control is executed by a microcomputer. By applying to, the rotational speed between 1 / n cycle cut and 1 / (n + 1) cycle cut can be obtained, and fine rotation speed control can be executed in the low speed region.

In the present invention, the cycle cut is changed each time the second and third counters count a predetermined number of times, so that any time between 1 / n cycle cut and 1 / (n + 1) cycle cut is arbitrary. The rotation speed can be obtained, so that the rotation speed control in the low speed region can be executed in detail.

In addition, in the present invention, by slowly changing the values of the second and third counters when the rotation speed is changed, the rotation speed change in the low speed region becomes fine and smooth, so that even in the transition period, the feeling of cold wind or the combustion state is maintained. There is no temporary deterioration.

Example 1

1 is a circuit diagram of a blower motor control device such as a warm air heater according to the present invention. In Fig. 1, reference numeral 1 denotes an insulation transformer, reference numeral 2 denotes a zero cross pulse generation circuit that generates a pulse when the input voltage reaches 0 V, and reference numeral 3 denotes a microcomputer as a means for controlling the rotation speed and zero cross pulse. The counter A (not shown) which counts the cycle of an AC power supply voltage according to the pulse from the generation circuit 2 is provided.

(5) is a thyristor, (4) is a firing circuit which controls this thyristor, and is comprised by the amplifier 7 and the thyristor trigger transformer 8, and (6) is a blowing motor.

Next, the operation of the first embodiment will be described with reference to FIGS. 2 and 4.

2 is a flowchart showing a rotation speed control program of the blower motor 6 stored in the microcomputer 3.

First, in FIG. 1, the AC power voltage waveform (a in FIG. 4) obtained through the insulation transformer 1 at both ends of the AC power input terminal IN is input to the zero cross pulse generating circuit 2, and FIG. It is converted into a pulse train such as and input to the microcomputer 3. The microcomputer 3 executes the processing according to the program shown in FIG. 2 every time the pulse is input.

That is, in Fig. 2, when the pulse is input to the microcomputer 3, the program is started and the control process of the blower motor 6 is executed once every time (step 10).

That is, the ratio is once per cycle of the AC power voltage waveform.

The microcomputer 3 counts the set number N of waveform cycles of the AC power supply voltage at each processing by the counter A provided in the memory (step 11). Then, it is determined whether or not the value of the counter A is set (step 12). Here, when it is not the set number of times, the microcomputer 3 outputs a high level signal. (Step 19). When the value of the counter A reaches the set number of times, a new set number n is set in the counter A (step 20), and the microcomputer 3 outputs a low level signal.

By repeating the above process, a square wave signal obtained by subtracting one cycle from the cycle set in the counter A is output.

When the set number of times is set in the counter A in step 20, the state of the flag provided in the memory of the microcomputer 3 is determined (step 13). If the content of the flag is 0, the flag is set to 1 (step 14), N is set in the counter A (step 15). If the content of the flag is 1, the flag is set to 0 (step 16), and (n + 1) is set in the counter A (step 17). That is, n and (n + 1) are alternately set in the counter A as the set number of times.

According to the program processing of the microcomputer 3 described above, a waveform obtained by subtracting one cycle from n cycles (1 / n cycle cut) and a waveform obtained by subtracting one cycle from a cycle of (n + 1) (1 / (n + The oscillation waveform (c in FIG. 4) in which the cycle cut of 1) is alternately repeated is output from the microcomputer 3.

When the oscillation waveform is input to the firing circuit 4 to control the thyristor 5, the voltage applied to the blower motor 6 is equal to 1 / n and 1 / (n + 1) as shown in FIG. The cycle cuts are alternating with alternating voltages.

As a result, the blower motor 6 can be operated at approximately half the rotational speed between the rotation speed of 1 / n cycle cut and the rotation speed of 1 / (n + 1) cycle cut, and burns kerosene and the like. It is possible to set a fine rotational speed suitable for the combustion amount in a warm air heater for heating the room using the combustion amount.

For example, if the air flow rate is too small at 1/3 cycle cut and the air flow rate is too large at 1/4 cycle cut, it is optimal to fit the combustion amount by alternating 1/3 and 1/4 cycle cut alternately. It can be set to a value close to the rotation speed.

Example 2

Further, in the first embodiment, it has been described that the rotation speed control is executed by alternately repeating cycle cuts of 1 / n and 1 / (n + 1) of the AC voltage waveform applied to the blower motor 6, but the microcomputer In the memory of (3), the second and third counters B and C for counting the number of cycle cuts of 1 / n and 1 / (n + 1) may be provided.

Next, the operation of the second embodiment will be described with reference to FIG. 3 is a flowchart of the program in the second embodiment of the processing unit for setting the set number of times in the counter A in step 20 of FIG.

In FIG. 3, when the setting frequency is set in the counter A, the state of the flag provided in the memory of the microcomputer 3 is determined (step 30). If the content of the flag is 0, the second counter B is counted (step 31), and it is determined whether or not the value of the counter B is a predetermined number of times N1 (step 32). (Step 35) When the predetermined number N1 is reached, the second counter B is cleared (step 33), the contents of the flag are set to 1 (step 34), and n is set to the counter A.

Similarly, if the content of flag is 1, a is not the third count the counter C and the (step 36), the counter C is determined whether or not the predetermined number N ₂ (step 37), the predetermined number of times N ₁ for as counter A When (n + 1) is set (step 40) and the predetermined number N ₂ is reached, the third counter C is cleared (step 39), and (n + 1) is set in the counter A.

By the program processing of the microcomputer 3 described above, an oscillation waveform in which a cycle cut of 1 / n of a predetermined number N ₁ and a cycle cut of 1 / (n + 1) of a predetermined number N ₂ is alternately repeated is a microcomputer. Is output from (3).

5 shows timing charts in the case where N ₁ = 2, N ₂ = 1 and 1/3 cycle cut and 1/4 cycle cut. In this case, by changing the values of N ₁ and N ₂ , an intermediate value between the rotational speed of the blower motor 6 at 1/3 cycle cut and the rotational speed at 1/4 cycle cut can be arbitrarily set. More precise rotation speed control is possible. As a result, it is possible to set the optimum rotational speed more suited to the combustion amount than the first embodiment, and a very good combustion state can be obtained even at low combustion.

Example 3

In addition, in the above embodiment, the control of the blower motor 6 enables the setting in the rotation speed control area, which could not be set in the past, but the set rotation speed is changed from the low speed area to the intermediate area or the intermediate area to the low speed area. In this case, the counters B and C of the second embodiment may be gradually changed.

For example, as shown in FIG. 6, when the heating value is changed from about to medium in a warm air heater or the like, the combustion flame gradually changes, and thus the rotation speed of the blower motor 6 also changes. As a result, the cycle is gradually changed from 1/3 cycle cut which is the setting value for weak combustion to 1/4 cycle cut which is the setting value for medium combustion. In this way, when the set value of the calorific value is changed, there is no feeling of cold wind or the combustion state temporarily deteriorated even in the transition period.

As described above, according to the present invention, since the cycle cut of 1 / n and 1 / (n + 1) is performed alternately with respect to the AC power voltage applied to the blower motor, the controllability in the continuous area of the blower motor is controlled. It is remarkably improved, and by this, it is possible to set the optimum rotational speed suitable for the combustion amount, and a very good combustion state is obtained even at the time of weak combustion.

In addition, according to the present invention, a second and a third counter are provided for counting the number of cycle cuts of 1 / n and 1 / (n + 1), and each of these second and third counters counts a predetermined number of times. Since the cycle cut is changed, the controllability in the low speed region of the blower motor is further improved.

In addition, according to the present invention, when the set speed of the blower motor is changed, the set speed is shifted while gradually changing the values of the second and third counters. In the transitional period, there is no feeling of cold wind or a temporary deterioration of the combustion state.

Claims (3)

An insulated transformer connected to an AC power supply terminal, a zero cross pulse generator circuit connected to the insulated transformer, and generating a pulse at a point where the AC power voltage from the insulated transformer crosses 0V, and the zero cross pulse generator circuit. A microcomputer having a counter for counting cycles of the waveform of the AC power supply voltage in accordance with a pulse generated by the zero-cross pulse generating circuit, and outputting an oscillation output signal obtained by subtracting one cycle from n cycles counted by the counter; A firing circuit connected to a computer and composed of an amplifier and a thyristor triser transformer and for firing a thyristor inserted between the blown motor and the AC power supply according to the oscillation output signal from the microcomputer, wherein the microcomputer has a low speed; The rotation speed control of the blower motor in the area And an oscillation output signal for controlling an oscillating output signal to alternately apply a voltage of 1 / n cycle cut and a low pressure of 1 / (n + 1) cycle cut to the blower motor. 2. The microcomputer of claim 1, wherein the microcomputer includes second and third counters for counting the number of cycle cuts of 1 / n and the number of cycle cuts of 1 / (n + 1), respectively. Blowing motor control device such as a hot air heater, characterized in that for changing the cycle cut every time. The set rotation speed of claim 2 is shifted while gradually changing the values of the second and third counters when changing the set rotation speed of the blower motor from the low speed region to the medium, high speed region, or the medium to high speed region. Blowing motor control device, such as a warm air heater.