JP3153438B2 - Hot air heater - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot air heater.

[0002]

2. Description of the Related Art In a hot air heater such as a gas hot air heater, a room air is sucked into a hot air passage by a blower, and the sucked indoor air is supplied to a heat source such as a burner in the middle of the air passage. It is generally known that the air is heated by the air and sent out into the room. In this type of air, an air filter for removing dust, dust and the like in the indoor air sucked into the air passage is usually provided in the air passage. It is loaded.

On the other hand, in this type of hot air heater, the actual rotation of the blower is set while setting the target rotation speed of the blower based on a detected room temperature obtained by a room temperature sensor or a set room temperature set by a user or the like. It is generally known that the number of rotations is detected and feedback control is performed so that the detected rotation speed matches a target rotation speed. In this case, this feedback control is performed using a microcomputer or the like, for example, as follows.

That is, the standard relationship between the rotation speed of the blower and the amount of energization is stored in advance in a memory as a reference value characteristic of the amount of energization using a data table, an arithmetic expression, or the like, and the operation of the warm air heater is performed. At this time, when the target rotation speed of the blower is set, a reference instruction value of the amount of power to the blower is determined from the target rotation speed according to the reference value characteristic. The reference instruction value is appropriately increased or decreased so that the deviation between the detected rotation speed of the blower and the target rotation speed becomes zero, and the corrected instruction value is instructed to the energizing circuit of the motor of the blower. Thus, the blower is energized so that its actual rotation speed (detected rotation speed) matches the target rotation speed.

In a warm air heater that performs feedback control of the number of revolutions of the blower as described above, dust and dirt adhere to the air filter due to long-term use of the warm air heater and the like. When clogging of the air filter occurs, the airflow of the blower decreases and the load becomes lighter. Therefore, as described above, the instruction value of the energization amount of the blower for controlling to the target rotation speed or the actual value corresponding to the instruction value The amount of electricity decreases as clogging of the air filter progresses. When the clogging of the air filter progresses to a certain degree or more, the airflow becomes insufficient in a state where the rotation speed of the blower is controlled to the target rotation speed, causing an excessive temperature rise in the temperature in the air passage and the delivered hot air. .

For this reason, the applicant of the present application, when performing the above-described feedback control for making the rotation speed of the blower coincide with the target rotation speed, sets the indicated value of the energization amount of the blower to each rotation speed of the blower. When the air filter has clogged to such an extent that an appropriate air volume cannot be obtained by the feedback control, the indicated value of the energization amount is changed to the allowable lower limit value. (See, for example, Japanese Patent Application No. 5-290780). By doing in this way, the actual rotation speed (detection rotation speed) of the blower naturally increases (becomes larger than the target rotation speed) as the load decreases due to the progress of clogging of the air filter. Insufficient air volume due to clogging of the air filter is compensated.

Further, in the device proposed by the applicant of the present invention, the clogging of the air filter further progresses, and the deviation between the target rotation speed, the detection rotation speed and the detection rotation speed (detection rotation speed−target rotation speed) is required. When it becomes larger than a certain amount, the indicated value of the amount of energization is increased, thereby increasing the amount of energization of the blower to positively increase the number of revolutions of the blower and eliminating insufficient air volume due to severe clogging of the air filter. Like that.

However, according to a further study by the inventors of the present invention, even in the case of the same type of hot air heater, the clogged state of the air filter should originally stop the feedback control depending on each product. Despite reaching the state, it has been found that there may be a problem that the feedback control of the rotation speed of the blower is continued until the air filter is further clogged. When the inventors of the present application examined the reason, the following findings were obtained.

That is, the actual amount of current supplied to the blower basically corresponds to the indicated value given to the current supply circuit in a predetermined relationship. In some cases, the actual amount of current with respect to the indicated value of the amount of current differs relatively from the standard amount of current due to variations in the amount of power. For example, if the indicated value of the energization amount is 100 mA, the energization amount of the blower is approximately 100 mA.
However, depending on the product, the actual energization amount may be, for example, 80 mA.

[0010] In particular, in a warm air heater in which the actual energization amount is smaller than the indicated value of the energization amount of the blower, the feedback control of the blower to a target rotation speed is performed. The indicated value of the energization amount is larger than a standard indicated value.

For this reason, in such a warm air heater, the clogged state of the air filter when the command value of the energization amount falls to the allowable lower limit value during the feedback control of the rotation speed of the blower is a standard condition. It is considered that the progress has progressed excessively as compared with the case, thereby causing the above-mentioned inconvenience.

[0012]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned inconvenience, and it is possible to prevent the air filter from being clogged excessively irrespective of the variation in the characteristic of the actual energization amount with respect to the indicated value of the energization amount of the blower. It is possible to eliminate a situation where the rotation speed of the blower is continuously controlled to the target rotation speed, and it is possible to eliminate a shortage of air volume due to the clogging of the air filter at an appropriate timing corresponding to the clogging state. It is intended to provide a hot air heater.

[0013]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a ventilation path in which an air filter is mounted, a room air is sucked into the ventilation path, and the sucked room air is heated by a heat source. A fan for sending hot air, a room temperature detecting means for detecting a room temperature, a target rotation speed setting means for setting a target rotation speed of the blower based on at least the detected room temperature of the room temperature detection means, and a rotation speed of the blower. A first storage means for storing in advance a reference value characteristic indicating a relationship between a rotation speed of the blower and a reference instruction value of the amount of current supplied to the blower; a rotation speed of the blower; A second storage unit that stores and holds in advance a lower limit characteristic indicating a relationship between an instruction value of an energization amount of the blower and an allowable lower limit value;
A reference indication value of the amount of electricity supplied to the blower obtained from the target rotation speed set by the target rotation speed setting means in accordance with the reference value characteristic of the first storage means is used as the target rotation speed. When an instruction value that is increased or decreased is generated and output so that the numbers match, when the instruction value falls below the allowable lower limit obtained from the target rotation speed according to the lower limit characteristic of the second storage means. An energization instruction value generating means for generating and outputting an energization amount instruction value of the blower so as to increase the rotation speed of the blower regardless of the target rotational speed; and an instruction value generated by the energization instruction value generation means. In the warm air heater provided with an energizing circuit for energizing the blower according to the temperature of the inside of the air duct, the temperature detecting means for detecting the temperature in the air duct, and the energizing instruction value generating means, wherein When the detected temperature of the air passage temperature detecting means is equal to or higher than a predetermined temperature while generating and outputting the indicated value so as to match the detected rotation speed, the energizing instruction value generating means at that time is Instruction value deviation calculation means for calculating a deviation between an instruction value and an allowable lower limit value obtained according to a lower limit value characteristic of the second storage means from the target rotation speed;
A reference value obtained by changing the reference indicated value and the allowable lower limit in the reference value characteristic of the first storage means and the lower limit characteristic of the second storage means by the indicated value deviation calculated by the indicated value deviation calculating means, respectively. Characteristic updating means for newly storing the characteristic and the lower limit characteristic in the first storage means and the second storage means, respectively, after the reference value characteristic and the lower limit characteristic are updated by the characteristic updating means. The energization instruction value generating means may newly generate and output the instruction value based on a reference value characteristic and a lower limit characteristic stored and held in the first storage means and the second storage means, respectively.

The energization instruction value generating means is configured to output the instruction value when the instruction value generated and output so as to match the detected rotational speed with the target rotational speed is equal to or less than the allowable lower limit value.
Means for generating and outputting the permissible lower limit as an instruction value until the deviation between the target rotational speed and the detected rotational speed reaches a predetermined amount, and when the deviation between the target rotational speed and the detected rotational speed exceeds a predetermined amount. Means for increasing an instruction value to be generated / output.

[0015]

According to the present invention, the energization instruction value generating means includes:
An instruction value of the energization amount is generated and output to the energization circuit by increasing or decreasing the reference instruction value based on the reference value characteristic of the first storage means so that the detected rotational speed matches the target rotational speed of the blower. When, that is, while the control to the target rotation speed of the blower is performed, if the clogged state of the air filter proceeds to a certain clogged state,
Normally, the indicated value of the amount of energization drops below the allowable lower limit based on the lower limit characteristic of the second storage means. For this reason, the energization instruction value generation means generates an instruction value of the energization amount so as to increase the rotation speed of the blower and outputs the instruction value to the energization circuit, thereby compensating for the insufficient air volume due to clogging of the air filter. Will be

On the other hand, in the case where the actual energizing amount of the energizing circuit to energize the blower with respect to the instructed value of the energizing amount is smaller than a normal energizing amount, the target When the rotation speed is controlled, even if the air filter clogs up to a certain clogged state (a state where the rotation speed of the blower should be increased from the target rotation speed), Does not decrease to the permissible lower limit value, and therefore, the energization instruction value generation unit attempts to continue generating and outputting an instruction value for controlling the rotation speed of the blower to the target rotation speed. However, in this state,
Due to the lack of air volume due to clogging of the air filter, the temperature in the air passage increases excessively, and the temperature detected by the air passage temperature detection means becomes equal to or higher than a predetermined temperature. At this time, the deviation between the current instruction value of the energization instruction value generation unit and the allowable lower limit based on the lower limit characteristic of the second storage unit is obtained by the instruction value deviation calculation unit, and the obtained instruction value deviation is calculated. A reference value characteristic and a lower limit value characteristic obtained by changing the reference instruction value and the allowable lower limit value in the reference value characteristic of the first storage means and the lower limit characteristic of the second storage means, respectively; The data is stored and held in the first storage means and the second storage means. In this case, the instruction value of the energization instruction value generation unit when the temperature detected by the temperature detection unit in the air passage becomes equal to or higher than the predetermined temperature indicates that the clogged state of the air filter is in a state where the rotation speed of the blower should be increased. , It corresponds to the original permissible lower limit of the hot air heater. Therefore, as described above, the reference value characteristic and the lower limit value characteristic newly stored and held in the first storage means and the second storage means are different from the actual energization amount with respect to the instruction value of the energization amount of the blower in the hot air heater. It will be consistent with the characteristics. Then, the energization instruction value generation means,
Thereafter, based on the reference value characteristic and the lower limit characteristic updated as described above, the instruction value is generated and output in the same manner as in the above-described normal case, and thus the clogged state of the air filter is as described above. In a state where the air conditioner has progressed to the clogged state, the number of revolutions of the blower is increased, whereby the shortage of the air volume is compensated, and further increase in the temperature in the air passage is suppressed.

In the present invention, when the indicated value falls below the allowable lower limit value due to clogging of the air filter, the energized instruction value generating means first generates and outputs the allowable lower limit value as an indicated value. . At this time, the energizing circuit energizes the blower with a constant energizing amount, and the number of rotations of the blower naturally increases due to a decrease in load accompanying progress of clogging of the air filter. This suppresses a decrease in air flow due to clogging of the air filter. Then, when the clogging of the air filter further progresses and the deviation between the detected rotation speed of the blower and the target rotation speed exceeds a predetermined amount, the energization instruction value generating means increases the instruction value, and Increase the amount of electricity to the blower. Thereby, the rotation speed of the blower is positively increased, and a necessary air volume is secured even in a state where the clogging of the air filter has greatly progressed.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described with reference to FIGS. 1 is a system configuration diagram of the hot air heater of the present embodiment, FIG. 2 is a perspective view of the hot air heater as viewed from the front side, FIG. 3 is a perspective view of the hot air heater as viewed from the rear side, FIG. 4 is a block diagram of a main part of the hot air heater, FIG. 5 is a flowchart for explaining the operation of the blower of the hot air heater, and FIG.
7 is a diagram for explaining the operation of the blower of the warm air heater.

Referring to FIGS. 1 to 3, a hot air heater 1 according to the present embodiment is a gas hot air heater, and a heater main body 3 built in a housing 2 disposed indoors has a duct. 4
(Blower), convection fan 5 (blower), gas burner 6
(Heat source), a duct 7 and a gas supply pipe 8, and are controlled by a control unit 9.

The duct 4 has an air inlet 10 for taking in room air at the rear of the housing 2 and a hot air outlet 11 at the lower front of the housing 2.
An air filter 12 is attached to the air inlet 10 to prevent dust and dirt from flowing into the duct 4.
A movable louver 13 for adjusting the degree of opening and the blowing direction of the hot air is attached to the hot air outlet 11, and a gad motor 14 for driving the movable louver 13 is provided. A duct temperature sensor 15 (air temperature sensor in the air passage) formed of a thermistor is attached to a location near the air intake port 10 inside the duct 4. It outputs an electrical output corresponding to the temperature inside the control unit 9.

The convection fan 5 has a motor 16 whose rotation speed increases in proportion to the supplied current, and rotating blades 17 which are driven to rotate by the motor 16. The indoor air s is sucked into the inside of the air conditioner 4. Then, the sucked indoor air s is mixed with the combustion exhaust gas h of the gas burner 6 incorporated in the duct 4 and heated, and is blown out from the hot air outlet 11 as hot air m. The convection fan 5 is provided with a rotation speed sensor 18 (rotation speed detecting means) for detecting the rotation speed. The rotation speed sensor 18 is configured by a Hall IC that generates a predetermined number of pulses for each rotation of the motor 16, and provides its output to the control unit 9.

Gas burner 6 incorporated in duct 4
Has a combustion plate 20 disposed in a combustion drum 19 and an ignition electrode 21 for igniting an air-fuel mixture disposed downstream of the combustion plate 20. The combustion cylinder 19 of the gas burner 6 communicates with the duct 4, and the combustion exhaust h is discharged into the duct 4. A thermocouple 22 for detecting abnormal combustion is disposed downstream of the combustion plate 20. The thermocouple 22 is exposed to the combustion flame of the gas burner 6 to generate an electromotive force, and the electromotive force is transmitted to the control unit 9. Output to

The duct 7 is a passage for supplying the indoor air s and the fuel gas to the gas burner 6.
And has a suction port 23 for room air s which is communicated with the inside of the combustion drum 19 and is defined in the duct 4 and is incorporated in the housing 2 and is opened at the back of the housing 2. On the way from the suction port 23 of the duct 7 to the gas burner 6,
A nozzle 24 attached to the tip of the gas supply pipe 8 is introduced. The indoor air s is sucked into the duct 7 from the suction port 23 by the rotation of the convection fan 5, and the sucked indoor air s is ejected from the nozzle 24 of the gas supply pipe 8 in the process of reaching the gas burner 6. The mixture with the gas is supplied to the gas burner 6. In addition, the suction port 23
Are covered by the air filter 12. A room temperature sensor 26 composed of a thermistor is attached to a location near the suction port 23 inside the duct 7, and the duct temperature sensor 15 outputs an electric output corresponding to the room temperature to the control unit 9.

The gas supply pipe 8 having the nozzle 24 introduced into the duct 7 is provided with solenoid valves 27 and 28 and a proportional valve 29 in this order from the upstream side.

The solenoid valves 27 and 28 allow the fuel gas to pass in the direction of the nozzle 24 when the valve is opened by energization, and block the passage of the fuel gas when the valve is closed by stopping the energization.

The proportional valve 29 is a valve whose opening increases in accordance with the magnitude of the energizing current, and the energizing current is proportional to the amount of gas supplied to the gas burner 6.

An operation switch 31 is provided on the upper surface of the housing 2.
A temperature control switch 32 is provided inside an opening / closing lid 2a (see FIG. 2) provided on the upper surface of the housing 2.
33 and a filter lamp 34 are provided.

The operation switch 31 instructs the control unit 9 to start or end the heating operation by ON / OFF operation.

The temperature control switches 32 and 33 are push button switches for setting the room temperature, and when pressed, raise and lower the set room temperature by 1 ° C. to instruct the control unit 9.

The lighting of the filter lamp 34 informs the user of the necessity of cleaning due to clogging of the air filter 12 and is controlled by the control unit 9 to be energized.

Referring to FIG. 4, the control unit 9 includes an operation control circuit 35, a temperature control control circuit 36, a combustion control circuit 37,
A fan control circuit 38, a clogging determination circuit 39, and a fan energization circuit 40 are provided.

The operation control circuit 35 includes an instruction signal from the operation switch 31, an electromotive force transmitted by the thermocouple 22,
Further, based on an operation stop signal sent from the clogging determination circuit 39 as described later, the energization of the solenoid valves 27 and 28 is controlled.

The temperature control circuit 36 determines the combustion intensity of the gas burner 6 based on the room temperature detected by the room temperature sensor 26 and the set room temperature set by the temperature control switches 32 and 33.
A combustion intensity signal indicating the determined combustion intensity is output to the combustion control circuit 37 and the fan control circuit 38.

The combustion control circuit 37 determines the amount of gas to be supplied to the gas burner 6 based on the combustion intensity signal given from the temperature control circuit 36, and determines the proportional valve current at which the opening degree corresponding to this amount of gas is obtained. Power is supplied to the proportional valve 29. Further, the combustion control circuit 37 controls energization to the ignition electrode 21.

The fan control circuit 38 is constituted by a microcomputer or the like.
1, 42 (first and second storage means), a target rotation speed setting unit 43 (target rotation speed setting unit), a power supply instruction value generation unit 44
(Energization instruction value generation means), instruction value deviation calculation unit 45 (instruction value deviation calculation means), and characteristic update unit 46 (characteristic update means)
Is provided.

The storage units 41 and 42 may be single or separate R
The storage unit 41 includes a reference value characteristic indicating the relationship between the rotation speed of the convection fan 5 and the reference instruction value of the amount of power to the motor 16 of the convection fan 5 as indicated by a solid line a in FIG. Are stored and held as a data table, for example. The reference value characteristic a indicates an indicated value of a standard amount of current supplied to the motor 16 corresponding to each rotation speed of the convection fan 5 in a normal case where the air filter 12 is not clogged. In addition, as shown by the solid line b in FIG. 6, the storage unit 42 has a lower limit characteristic indicating the relationship between the rotation speed of the convection fan 5 and the allowable lower limit of the indicated value of the amount of power to the motor 16 of the convection fan 5. Are stored and held as a data table, for example. The lower limit value characteristic b indicates an instruction value of a standard energization amount at which a proper air volume can be secured at each rotation speed of the convection fan 5 when clogging of the air filter 12 progresses. The indicated value is set slightly smaller than the reference value characteristic a.

The target rotation speed setting unit 43 includes a temperature control circuit 3
A target rotation speed of the convection fan 5 for taking in an amount of room air corresponding to the combustion intensity of the gas burner 6 into the ducts 4 and 7 based on the combustion intensity signal given from the gas burner 6 is set in accordance with a predetermined data table or the like. I do. In this case, as shown in FIG. 6, as the combustion intensity of the gas burner 6 increases, for example, to N1, N2,..., Nn, the combustion intensity increases such that the target rotation speed increases to M1, M2,. It is determined corresponding to.

The energization instruction value generation unit 44 basically generates a reference instruction value of the energization amount corresponding to the target rotation speed from the target rotation speed set as described above according to the reference value characteristic a of the storage unit 41. The actual reference speed (detected rotation speed) of the convection fan 5 is obtained by correcting the reference reference value obtained in accordance with the deviation between the target rotation speed and the detection rotation speed of the convection fan 5 given from the rotation speed sensor 18. ) Is generated to match the target rotation speed, and an instruction value of the energization amount is generated and output to the fan energization circuit 40. When the command value generated as described above becomes equal to or less than the allowable lower limit value obtained from the set target rotation speed according to the lower limit value characteristic b of the storage unit 42, the energization command value generation unit 44 The indication value is generated in another manner, which will be described later.

The indicated value deviation calculating section 45 responds to a characteristic updating instruction signal sent from the clogging judging circuit 39 as will be described later, and indicates the indicated value of the energizing indicated value generating section 44 at that time and the target rotation at that time. From the number, a deviation from the allowable lower limit value obtained according to the lower limit characteristic b of the storage unit 42 is obtained.

The characteristic updating unit 46 includes a clogging determination circuit 39
The reference value characteristic a and the lower limit characteristic b of the storage units 41 and 42 are updated in accordance with the instruction value deviation obtained by the instruction value deviation calculation unit 45 in response to the characteristic update instruction signal, and are newly stored in the storage units 41 and 42. Is stored.

The fan energizing circuit 40 is configured by using a power source, a resistor, a semiconductor switch element, an operational amplifier, and the like (not shown).
Energizes the motor 16 of the convection fan 5 with the amount of energization indicated by the indicated value generated and output.

The clogging judging circuit 39 includes comparators 47 and 4 to which the temperature detected by the duct temperature sensor 15 is input.
8,49.

When the temperature detected by the duct internal temperature sensor 15 rises above the first predetermined temperature, the comparing section 47 issues a characteristic update instruction for updating the reference value characteristic a and the lower limit value characteristic b of the storage sections 41 and 42. The signal is output to the fan control circuit 38.

When the temperature detected by the in-duct temperature sensor 15 rises above a second predetermined temperature (> first predetermined temperature), the comparing section 48 energizes the filter lamp 34 to light it.

The comparator 49 outputs an operation stop instruction signal to the operation control circuit 35 when the temperature detected by the duct temperature sensor 15 rises to a third predetermined temperature (> second predetermined temperature) or higher.

Next, the operation of the gas warm air heater 1 of this embodiment will be described.

When the user turns on the operation switch 31, the operation is started under the control of the control unit 9 accordingly. At this time, the control unit 9 energizes the motor 16 of the convection fan 5, the ignition electrode 21, and the solenoid valves 27 and 28, and the indoor air s is drawn into the ducts 4 and 7 by the rotation of the rotating blades 17 of the convection fan 5. Is started, and gas supply to the gas burner 6 and its ignition and combustion are started.

On the other hand, the indoor air s taken into the duct 4 from the air suction port 10 through the air filter 12 by the rotation of the rotary blades 17 is supplied to the combustion exhaust h of the gas burner 6.
Is mixed with the hot air m, and the hot air outlet 11
From the room.

In such an operation, the control of the power supply to the motor 16 of the convection fan 5 by the control unit 9 is performed based on the flowchart shown in FIG.

That is, in STEP 1, the fan control circuit 38 matches the detected rotation speed of the rotation speed sensor 18 with the target rotation speed set by the target rotation speed setting section 43 from the combustion intensity signal output from the temperature control control circuit 36. The amount of current supplied to the motor 16 is feedback-controlled via the fan current supply circuit 40 so as to cause the motor 16 to operate. More specifically, the energization instruction value generation unit 44 of the fan control circuit 38
The reference instruction value obtained from the target rotation speed set in Step 3 in accordance with the reference value characteristic of the storage unit 41 is appropriately corrected according to the deviation between the target rotation speed and the detected rotation speed, so as to eliminate the deviation. An amount indication is generated and output to the fan energization circuit 40. And the fan energizing circuit 4
A value of 0 basically causes the motor 16 to be energized with an energization amount corresponding to the given instruction value, whereby feedback control is performed so that the target rotation speed matches the detected rotation speed.

In this case, if the air filter 12 is not clogged or is light, the indicated value generated and output by the energized indicated value generation unit 44 is generally the reference value characteristic shown in FIG. The air filter 12 is located in a range from the vicinity of the line a to the vicinity of the line of the lower limit characteristic b, and as the clogging of the air filter 12 progresses, it decreases toward the allowable lower limit of the lower limit characteristic b. For example, assuming that the combustion intensity of the gas burner 6 is N4, the target rotation speed is M4, and if the clogging of the air filter 12 proceeds slightly with the detected rotation speed controlled to the target rotation speed M4, the energization instruction is issued. The indicated value of the value generating unit 44 is generally from the reference indicated value S4 to the allowable lower limit S4 '.
(See operation line c in FIG. 7). If the amount of current actually flowing through the motor 16 with respect to the instruction value of the energization instruction value generation unit 44 becomes relatively small due to variations in the resistance of the fan energization circuit 40 or the characteristics of the power supply, etc. Since the indicated value of the energization amount for matching the target rotation speed and the detected rotation speed becomes large, for example, in a state larger than the reference indicated value, the indicated value decreases as the clogging of the air filter 12 progresses. Sometimes it goes.

In STEP 2, the comparing section 47
It is determined whether or not the temperature detected by the duct temperature sensor 15 is equal to or higher than a first predetermined temperature. At this time, normally, the detected temperature in the duct 4 does not rise until reaching the first predetermined temperature (NO in STEP2), and proceeds to STEP5.
The processing when the detected temperature in the duct 4 rises to the first predetermined temperature or higher (YES in STEP 2) will be described later.

In STEP 5, the energization instruction value generation unit 4
Step 4 determines whether or not the indicated value generated in STEP 1 is equal to or less than an allowable lower limit in the lower limit characteristic of the storage unit 42. At this time, if the air filter 12 is not clogged or is light (NO in STEP5), the ST
The instruction value generated to match the target rotation speed with the detection rotation speed in EP1 is a value larger than the allowable lower limit value. In this case, the process returns to STEP 1 and the detected rotation speed is set to the target rotation speed. The matching control continues. On the other hand, if the clogging of the air filter 12 has progressed to a moderate degree, S
The indicated value generated in TEP1 is usually equal to or smaller than the allowable lower limit (YES in STEP5), and in this case, the STE
Proceed to P6. For example, in FIG.
In the case of (combustion intensity N4), if the clogging of the air filter 12 has progressed to a moderate degree, the indicated value generated in STEP1 is usually S4 'or less.
TEP6 is executed. It should be noted that when the clogging of the air filter 12 is at a moderate level, the motor 16 of the convection fan 5 is energized so that the detected rotation speed matches the target rotation speed with an instruction value less than the allowable lower limit value. Then, the amount of air flowing through the duct 4 tends to be insufficient, and the temperature inside the duct 4 rises excessively.

In STEP 6, the energization instruction value generation unit 4
In No. 4, because the instruction value for matching the detected rotation speed to the target rotation speed is equal to or less than the allowable lower limit value, the feedback control is stopped, and the allowable lower limit value is output to the fan energizing circuit 40 as the instruction value. Proceed to.

At this time, in FIG.
(Combustion intensity N4), the indicated value is the target rotational speed M4.
Is fixedly held at the allowable lower limit value S4 'corresponding to the specified value, and the fan energizing circuit 40 receiving the indicated value energizes the motor 16 with a constant energized amount corresponding to the indicated value. For this reason, as the clogging of the air filter 12 progresses in this state, the load on the motor 16 decreases, and the rotation speed of the convection fan 5 decreases as shown in FIG.
(The difference between the detected rotation speed and the target rotation speed increases) as shown by the operation line d. Thereby, a necessary air volume is secured.

In the process of generating and outputting the allowable lower limit value as the indicated value in this way, it is determined in STEP 7 whether (detected rotation speed−target rotation speed) has reached a specified value or more. Until the number of rotations-the target number of rotations reaches a specified value or more (NO in STEP7), the processing in STEP6 is performed. Then, when the clogging of the air filter 12 progresses severely and (detected rotation speed−target rotation speed) ≧ specified value,
In STEP8, the energization instruction value generation unit 44 increases the instruction value by a predetermined amount, and proceeds to STEP9. For example, when the target rotational speed is M4 in FIG. 6, the indicated value is increased by ΔT from the allowable lower limit S4 '. As a result, the energization amount of the motor 16 by the fan energization circuit 40 is increased by an amount corresponding to the increase in the indicated value, and the rotation speed of the convection fan 5 is positively increased so as to secure a required air volume.

Next, in STEP 9, it is determined whether or not (detected rotation speed−target rotation speed) ≦ constant value holds.
If the condition is satisfied (YES), the process returns to STEP1, and if not (NO), the process proceeds to STEP10.

That is, if clogging of the air filter 12 is eliminated by cleaning during the process, (detected rotation speed-target rotation speed) becomes equal to or less than a predetermined value. In this case, the detected rotation speed becomes equal to the target rotation speed. ST that generates an indication value to match
It returns to the feedback control of EP1.

If the condition in STEP 9 is not satisfied, after a predetermined time has elapsed in STEP 10,
In STEP 11, it is determined whether or not the indicated value increased by the predetermined amount is equal to or larger than the reference indicated value in the reference value characteristic of the storage unit 41, and when it is less than the reference indicated value (STEP 1).
(NO at 1) returns to STEP 8, and the energization instruction value generation unit 44 further increases the instruction value by a predetermined amount. Also, when the instruction value ≧ the reference instruction value (YES in STEP 11)
In STEP 12, the energization instruction value generation unit 44
Outputs the reference instruction value to the fan energizing circuit 40, and returns to STEP6.

At the stage where the clogging of the air filter 12 is severely progressed by the processing of STEPs 8 to 12, the instruction value of the energization instruction value generation unit 44 changes from the allowable lower limit value to the reference instruction value every predetermined time. Is gradually increased by a predetermined amount. Thereby, the rotation speed of the convection fan 5 gradually increases so that a required air volume can be secured (see an operation line e in FIG. 7). In this case, the indication value is gradually increased as described above in order to mitigate a transient phenomenon such as an overshoot of the rotation speed of the convection fan 5 due to a sudden increase in the indication value. In addition, in the case of severe clogging of the air filter 12, the increase in the indicated value is limited with the reference indicated value as an upper limit in order to prevent an increase in load and noise due to excessive high-speed rotation of the convection fan 5. is there.

When the air filter 12 becomes clogged severely and the airflow becomes insufficient even if the rotation speed of the convection fan 5 is increased by increasing the indicated value as described above, the duct 4 The temperature inside the duct rises excessively, and the temperature detected by the duct temperature sensor 15 becomes equal to or higher than the second predetermined temperature or the third predetermined temperature of the comparison sections 48 and 49. At this time, the comparison unit 4
When the detected temperature is equal to or higher than the second predetermined temperature, the filter lamp 34 is turned on to notify the user that cleaning of the air filter 12 is necessary. When the detected temperature becomes equal to or higher than the third predetermined temperature, the comparing section 49 outputs an operation stop signal to the operation control circuit 35 to stop the operation of the gas warm air heater 1.

By the way, in the control of the convection fan 5 as described above, the motor 16 does not respond to the instruction value of the energization instruction value generation unit 44 due to the resistance of the fan energization circuit 40 and the variation of the characteristics of the power supply. When the amount of current flowing through the motor becomes relatively small, the instruction value of the amount of current for matching the target rotation speed and the detected rotation speed in STEP 1 becomes larger than in the normal case. In such a case, even if the clogging of the air filter 12 progresses from the light stage to the medium stage, the indication value of the energization indication value generation unit 44 is the second value.
Without lowering to the permissible lower limit value of the lower limit characteristic of the storage unit 42, the energization instruction value generation unit 44 sets the instruction value as the clogging of the air filter 12 progresses in order to match the target rotation speed with the detected rotation speed. Is further reduced. However, in such a state, the air volume tends to be insufficient, so the duct 4
Temperature (the temperature detected by the duct temperature sensor 15) increases. For this reason, in STEP 2 of FIG. 5, the temperature detected by the duct internal temperature sensor 15 becomes equal to or higher than the first predetermined temperature of the comparison unit 47 (YES).

At this time, in STEP 3, the indicated value deviation calculating section 45 of the fan control circuit 38 determines the current indicated value of the energizing indicated value generating section 44 and the lower limit value characteristic of the storage section 42 according to the output of the comparing section 47. The deviation from the allowable lower limit is determined as the indicated value deviation.

Next, in STEP 4, the characteristic updating unit 4
6 are storage units 41 and 42 according to the obtained indicated value deviation.
Are updated, and the updated characteristics are newly stored and held in the storage units 41 and 42. In this case, the updating of the reference value characteristic and the lower limit value characteristic is performed by increasing the reference instruction value and the lower limit instruction value corresponding to each rotation speed in those characteristics by the instruction value deviation.

Specifically, in FIG. 6, when the target rotational speed is M4, the indicated value when the temperature detected by the duct temperature sensor 15 becomes equal to or higher than the first predetermined temperature is represented by Sx (> S
4 ′), the indicated value deviation ΔS obtained by the indicated value deviation calculating unit 45 is (Sx−S4 ′). At this time, the reference value newly stored in the storage units 41 and 42 by the characteristic updating unit 46 is stored. The value characteristic and the lower limit characteristic have a form in which the original reference value characteristic a and the lower limit characteristic b are translated by the indicated value deviation ΔS in the direction of increasing the indicated value, as indicated by imaginary lines a ′ and b ′, respectively. Characteristics.

The newly set reference value characteristic a ′ and lower limit value characteristic b ′ match those of the resistance of the fan energizing circuit 40 and the characteristics of the power supply.

After the reference value characteristic and the lower limit characteristic are updated in this way, the above-described processing is performed based on the updated reference value characteristic and lower limit characteristic. In this case, in the determination in STEP5, the instruction value of the energization instruction value generation unit 44 is equal to or less than the allowable lower limit value in the new lower limit characteristic, and thus the clogging of the air filter 12 is performed in the same manner as in the normal case described above. The processing after STEP 6 is performed along with the progress, and the rotation speed of the convection fan 5 is controlled so as to secure a required air volume.

Therefore, according to the gas warm air heater 1 of the present embodiment, the motor energization instruction value generation unit 44 is controlled by the motor energization instruction value generation unit 44 due to variations in the resistance of the fan energization circuit 40 and the characteristics of the power supply. Even in the case where the amount of current actually flowing through the air filter 16 becomes relatively small, it is possible to appropriately control the convection fan 5 corresponding to the clogged state of the air filter 12.

Next, a second embodiment of the warm air heater of the present invention will be described with reference to FIGS. 1 to 4, 6 and 8.

The hot air heater of the present embodiment has the same configuration as the gas hot air heater 1 of the first embodiment.
Since only the control mode is different,
The description of the configuration is omitted using the same reference numerals as in the embodiment,
Only the control mode of the convection fan 5 will be described.

The motor 1 of the convection fan 5 in this embodiment
The energization control of No. 6 is performed according to the flowchart shown in FIG.

In this case, there is no clogging of the air filter 12 or the processing of STEPs 1 to 5 in the mild stage is the same as that of the first embodiment, and the energization instruction value generation unit 44 sets the detected rotation speed of the convection fan 5 to the target. An instruction value is generated so as to match the rotation speed and output to the fan energizing circuit 40. Further, when the temperature detected by the duct temperature sensor 15 becomes equal to or higher than the first predetermined temperature of the comparing unit 47, the characteristic updating unit 46 updates the reference value characteristics and the lower limit value characteristics of the storage units 41 and 42.

Then, the clogging of the air filter 12 progresses moderately, and in STEP 5, an instruction value for making the detected rotation speed coincide with the target rotation speed is stored in the lower limit value characteristic of the storage unit 42 (in the case where it is updated in STEP 4). When the current value becomes equal to or less than the allowable lower limit value in the updated lower limit value characteristic), the energization instruction value generation unit 44 performs the processing in STEPs 6 and 7 ((detected rotational speed-target rotational speed)) ≧ Until the value (until the clogging of the air filter 12 progresses severely), the allowable lower limit value is output to the fan energizing circuit 40 as an instruction value. Next, in STEP 7, the air filter 1
If the clogging of No. 2 progresses severely and (detected rotation speed−target rotation speed) ≧ predetermined value, in the loop processing in STEP8 to STEP10, the energization instruction value generation unit 44 determines the allowable value in the lower limit characteristic of the storage unit 42. The instruction value is generated while correcting (increasing) the lower limit value by a predetermined amount at predetermined intervals at a rate proportional to the detected rotation speed. In this case, in the present embodiment, the energization instruction value generation unit 44 basically generates the instruction value so that the detected rotation speed matches the target rotation speed, but if the clogging of the air filter 12 is severe. At the stage where
Since the indicated value is equal to or smaller than the allowable lower limit obtained by increasing / correcting the allowable lower limit in the lower limit characteristic of the storage unit 42 by a predetermined amount as described above, the power supply instruction value generator 44 determines the corrected allowable lower limit. Is output to the fan energizing circuit 40 as an instruction value. Incidentally, in the correction of the allowable lower limit value, the storage unit 4
2 is not modified.

As a result, the instruction value of the energization instruction value generation section 44 gradually increases with an increase / correction of the permissible lower limit value at fixed time intervals, and the rotation speed of the convection fan 5 decreases in the first embodiment. As in the case of, the airflow is raised so that the required air volume can be secured. The increase / correction of the allowable lower limit at regular intervals is performed until the finally corrected allowable lower limit reaches the reference instruction value in the reference value characteristic of the storage unit 41, and the reference lower limit is reached. Later, the reference instruction value is set to the fan energizing circuit 40.
Output to Further, in the process of increasing / correcting the allowable lower limit value at regular intervals, the air filter 12 is cleaned, and
If (detected rotation speed−target rotation speed) <constant value at 0, the process returns to STEP 1.

Therefore, also in the gas warm air heater 1 of the present embodiment, the motor 16 does not respond to the instruction value of the energization instruction value generation section 44 due to the variation of the resistance of the fan energization circuit 40 and the characteristics of the power supply. Even when the amount of current flowing actually becomes relatively small, it is possible to appropriately control the convection fan 5 corresponding to the clogged state of the air filter 12.

Although the present embodiment has been described by taking a gas hot air heater as an example, it goes without saying that the present invention can also be applied to an oil-type hot air heater or the like.

[0077]

As is apparent from the above description, according to the present invention, the reference value characteristic of the first storage means is controlled by the power supply instruction value generating means so that the detected rotation speed of the blower matches the target rotation speed. When the detected temperature of the air passage temperature detecting means is equal to or higher than a predetermined temperature while generating and outputting to the energizing circuit an instruction value obtained by increasing or decreasing the reference instruction value based on the A deviation (indicated value deviation) between the current indicated value and an allowable lower limit based on the lower limit characteristic of the second storage means, and the characteristic updating means determines the reference value of the first storage means by the indicated value deviation. A reference value characteristic and a lower limit characteristic obtained by respectively changing a reference instruction value based on the characteristic and an allowable lower limit value based on the lower limit characteristic of the second storage unit are newly stored and held in the first and second storage units. Is the updated reference value feature. And the output value of the blower energization amount is generated and output based on the lower limit characteristic, so that the air filter can be clogged regardless of the variation in the actual energization amount characteristic with respect to the blower energization instruction value. It is possible to eliminate a situation where the rotational speed of the blower is continuously controlled to the target rotational speed in an excessively advanced state, and the air volume is insufficient due to the clogging at an appropriate timing corresponding to the clogged state of the air filter. Can be eliminated.

Then, when the command value generated and output by the energization command value generating means so that the detected rotation speed matches the target rotation speed is equal to or less than the allowable lower limit, the target rotation speed and the detected rotation speed are compared. The allowable lower limit value is generated and output as an instruction value until the deviation of the rotation reaches a predetermined amount, and thereafter, when the deviation between the target rotation speed and the detected rotation speed exceeds the predetermined amount, the generation value to be generated and output is increased. By doing so, it is possible to accurately ensure the required air volume corresponding to the clogged state of the air filter.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram of a gas hot air heater according to an embodiment of the present invention.

FIG. 2 is a perspective view of the gas warm air heater of FIG. 1 as viewed from the front side.

FIG. 3 is a perspective view of the gas warm air heater of FIG. 1 as viewed from the rear side.

FIG. 4 is a block diagram of a main part of the gas warm air heater of FIG. 1;

FIG. 5 is a flowchart for explaining the operation of the blower of the gas warm air heater in the first embodiment.

FIG. 6 is a diagram for explaining the operation (first embodiment) of the blower of the gas warm air heater of FIG. 1;

FIG. 7 is a diagram for explaining the operation (first embodiment) of the blower of the gas warm air heater of FIG. 1;

FIG. 8 is a flowchart for explaining the operation of a blower of a gas warm air heater in a second embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Hot air heater, 4 ... Duct (blower), 5 ... Convection fan (blower), 6 ... Gas burner (heat source part), 15 ... Duct temperature sensor (Blower temperature detection means), 26 ... Room temperature sensor (Room temperature detecting means), 41, 42 ... storage unit, 43 ...
Target rotation speed setting unit, 44: energization instruction value generation unit, 45: instruction value deviation calculation unit, 46: characteristic update unit.

Claims (2)

(57) [Claims] 1. An air passage loaded with an air filter, a blower for sucking room air into the air passage, and sending out hot air generated by heating the sucked room air by a heat source, and a room temperature for detecting room temperature. Detection means, target rotation speed setting means for setting a target rotation speed of the blower based on at least the detected room temperature of the room temperature detection means, rotation speed detection means for detecting the rotation speed of the blower, rotation speed of the blower A first storage unit which stores in advance a reference value characteristic indicating a relationship between the amount of power supply of the blower and a reference instruction value, and a relationship between a rotation speed of the blower and an allowable lower limit value of the value of the amount of power supply to the blower. A second storage means which previously stores and retains the lower limit characteristic shown in the table, and a base value of the amount of electricity supplied to the blower obtained from the target rotation speed set by the target rotation speed setting means in accordance with the reference value characteristic of the first storage means. An instruction value is generated / outputted by increasing / decreasing the instruction value so that the rotation speed detected by the rotation speed detecting means matches the target rotation speed, and the instruction value is stored in the second storage from the target rotation speed. An energization instruction for generating and outputting an instruction value of an energization amount of the blower so as to increase the rotation speed of the blower irrespective of the target rotation speed when the value falls below the allowable lower limit obtained according to the lower limit characteristic of the means. A hot air heater comprising: a value generating means; and an energizing circuit for energizing the blower in accordance with the instruction value generated by the energizing instruction value generating means, wherein a temperature in the air path for detecting a temperature in the air path. When the detection means and the energization instruction value generation means generate and output the instruction value so that the detected rotation speed matches the target rotation speed, the temperature detected by the air passage temperature detection means is equal to or higher than a predetermined temperature. An instruction value deviation calculating means for calculating a deviation between an instruction value of the energization instruction value generating means at that time and an allowable lower limit value obtained from the target rotation speed in accordance with a lower limit characteristic of the second storage means; A reference value characteristic in which the reference instruction value and the allowable lower limit in the reference value characteristic of the first storage means and the lower limit characteristic of the second storage means are respectively changed by the instruction value deviation calculated by the instruction value deviation calculation means. And a characteristic updating means for newly storing the lower-limit characteristic in the first storage means and the lower-limit characteristic, respectively, wherein the reference value characteristic and the lower-limit characteristic are updated by the characteristic updating means. The energization instruction value generation means is characterized in that the energization instruction value generation means newly generates and outputs the instruction value based on the reference value characteristic and the lower limit characteristic stored and held respectively in the first storage means and the second storage means. Warm air heater to. 2. The system according to claim 1, wherein said energization instruction value generating means detects said target rotational speed when said instruction value generated and output so as to make the detected rotational speed coincide with said target rotational speed is equal to or less than said allowable lower limit value. Means for generating and outputting the permissible lower limit as an instruction value until the deviation from the rotation speed reaches a predetermined amount, and when the deviation between the target rotation speed and the detected rotation speed exceeds a predetermined amount,
2. A warm air heater according to claim 1, further comprising means for increasing an instruction value to be generated and output.