KR950002641B1 - Hot air heater - Google Patents

Abstract

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Description

Hot air heater

1 to 4 show one embodiment of the present invention.

1 is a configuration diagram showing a schematic structure of the FF type gas hot air heater.

2 is a graph showing the relationship between the temperature difference between the room temperature and the set temperature and the target value of the combustion amount of the gas burner.

3 is a graph showing the relationship between the amount of change in gas amount and time in normal operation and rapid operation.

4 is a flowchart showing the main control of the microcomputer.

* Explanation of symbols for main parts of the drawings

1: FF gas hot air heater (hot air heater) 2: hot air duct

3: convection fan (convection blower) 6: gas burner (burner)

10 microcomputer (control circuit) 11 dummyster (temperature detection means)

15: temperature control button (temperature setting means) 74: proportional control valve

The present invention relates to a warm air heater for heating the room by the heat of combustion generated by combustion.

Conventionally, for example, based on a set temperature set by a temperature control button and a detection temperature detected by an indoor temperature sensor, the amount of energization supplied to the proportional control valve disposed in the gas passage is gradually changed, There is a gas hot air heater that changes the amount of combustion to bring the room temperature closer to the set temperature.

Then, when the user wants a rapid change in the combustion amount of the gas burner, the set temperature is changed by operating the temperature control button. When the set temperature is changed, the gas-heated air heater is controlled to change the energization amount of the proportional control valve at a high speed so as to quickly approach the room temperature to the set temperature.

The conventional gas-heated air heater gradually changes the energization amount of the proportional control valve so that the room temperature and the set temperature always approach after the detection temperature reaches the set temperature. For this reason, when the amount of energization of the proportional control valve is changed at a high speed as described above, a hunting phenomenon occurs in which a certain relationship and some other steps pass and go while the room temperature approaches the set temperature. Particularly in the convection fan, the phenomenon caused inconvenience.

Therefore, in order to solve this inconvenience, the difference between the room temperature and the set temperature is determined, and when the difference is large, the energization amount of the proportional control valve is changed quickly, and when the difference is small, the electricity supply amount of the proportional control valve is changed slowly. Can be considered.

By the way, when, for example, a gas hot air heater is installed near a door of an interior, the room temperature hardly changes when the door is slightly opened or closed, but there is a possibility that the detection temperature detected by the indoor temperature sensor is greatly reduced at once. In this case, in the above gas-heated air conditioner, it is not necessary to increase the room temperature. However, the gas amount is changed by rapidly changing the energization amount of the proportional control valve. At this time, not only the stable state of the burner is disturbed, but also the inconvenience that the room temperature rises above the set temperature.

According to the present invention, when the user is required to change the burner's combustion amount rapidly, the burner's combustion amount can be changed rapidly and the hunting temperature does not occur even if the energization amount of the proportional control valve is changed step by step. It is an object of the present invention to provide a warm air heater that does not disturb the stable state of the burner even if confusion occurs.

The hot air heater of the present invention is a hot air duct for directing air to the room, a burner for burning the fuel to heat the air passing through the hot air duct, and a proportion to change the amount of fuel supplied to the burner according to the amount of energization. The temperature setting means having a control valve, a convection blower for generating an air flow to the room in the warm air duct, a temperature setting means for setting the temperature of the room, and a temperature detecting means for detecting the temperature of the room And a control circuit for varying the amount of energization supplied to the proportional control valve based on the set temperature set by the means and the detection temperature detected by the temperature detecting means, wherein the control circuit is provided to the proportional control valve. The amount of energization supplied is changed to the first predetermined speed during normal operation so that the temperature setting means is operated. The adopted technical means for changing to the first predetermined speed faster than the second predetermined speed.

(At normal operation)

The control circuit gently changes the energization amount supplied to the proportional control valve to the first predetermined speed slower than the second predetermined speed. In this way, since the energization amount supplied to the proportional control valve is slowly changed at the first predetermined speed, which is a slow speed, the combustion amount of the burner is gently changed even when the room temperature approaches the set temperature. For this reason, since the inside of a warm air duct changes gently with the temperature of the air which flows toward a room, the energization amount supplied to a proportional control valve does not go to any stage and another stage. That is, the hunting phenomenon does not occur.

In addition, even if the detection temperature detected by the temperature detection means decreases for a moment due to the confusion of the room temperature at a moment, the amount of gas supplied to the burner is hardly changed because the amount of energization supplied to the proportional control valve changes slowly. For this reason, the combustion state of a burner is stabilized.

(When the temperature setting means is operated)

When the temperature setting means is operated, the control circuit changes the energization amount supplied to the proportional control valve to a second predetermined speed faster than the first predetermined speed.

When the amount of energization supplied to the proportional control valve changes at a predetermined speed, which is a high speed, the amount of fuel supplied to the burner changes rapidly.

For this reason, the combustion amount of a burner changes rapidly, and it changes rapidly with the temperature of the air which flows inside a hot air duct toward a room.

When a rapid change in the burn amount of the burner is required by the user, the burn amount supplied to the burner changes rapidly, so that the heating effect desired by the user can be obtained quickly.

In addition, in the normal operation in which a rapid change in the burn amount of the burner is not required, the energization amount supplied to the proportional control valve changes slowly. For this reason, even if the amount of current supplied to the proportional control valve is controlled step by step, the hunting phenomenon does not occur as in the conventional apparatus, and the convection blower does not generate the hunting phenomenon, thereby reducing the noise of the convection blower. In addition, the burner can maintain a stable combustion state even if the room temperature is disturbed for a moment.

The hot air heater of the present invention will be described based on the embodiment shown in FIGS.

1 shows a schematic structure of an FF type gas hot air heater.

The FF gas hot air heater 1 includes a hot air duct 2, a convection blower 3, a combustion duct 4, a combustion blower 5, a gas burner 6, a heat exchanger 61 and a combustion case. 62 and the microcomputer 10 are provided.

The hot air duct 2 is a hot air passage that sucks indoor air from the suction port 21 and blows out the warm air from the jet port 22 toward the room. In addition, the inlet 21 is provided with a dummyster 11. The convection blower 3, the heat exchanger 61, the combustion case 62, and the gas burner 6 are disposed inside the hot air duct 2.

The convection blower 3 is a convection fan that is driven by the electric motor 31 and its electric motor 31 whose rotational speed changes in accordance with the amount of energization, and generates air flow in the hot air duct 2 to the room ( 32).

The combustion duct 4 is an air passage for supplying the gas burner 6 with the outdoor air sucked from the outside and the fuel gas introduced from the fuel gas supply means 7.

The combustion blower 5 is rotationally driven by the electric motor 51 and its electric motor 51 whose rotational speed changes according to the amount of energization, and the air is directed to the outside in the combustion duct 4 and the gas burner 6. It has a combustion fan 52 which produces | generates a flow.

The gas burner 6 is a burner of the present invention and has a combustion plate 64.

One end of the heat exchanger 61 is connected to the combustion case 62 to exchange heat between the air passing through the hot air duct 2 and the internal combustion heat. The other end of the heat exchanger 61 is connected to the exhaust duct 63. The combustion case 62 arrange | positions the thermocouple 12 and the spark electrode 13 downstream of the combustion plate 64. As shown in FIG. The exhaust duct 63 is an air passage for discharging the combustion exhaust of the mixer to the outside.

The fuel gas supply means 7 has a first kettle valve 71, a second kettle valve 72, a flow rate adjusting orifice 73, a proportional control valve 74 and a gas pipe 75 having them disposed.

When the first kettle valve 71 and the second kettle valve 72 are energized, the valve is opened, and when the energization is stopped, the valve is closed. The orifice 73 is disposed in parallel with the proportional control valve 74 to adjust the supply amount of fuel gas (hereinafter referred to as gas amount). The proportional control valve 74 changes the opening ratio of the gas pipe 75 in accordance with the energization amount, thereby changing the supply pressure of the fuel gas to adjust the gas amount of the fuel gas.

The microcomputer 10 is a control circuit of the present invention, and inputs a signal from the dummyster 11, the thermocouple 2, the spark electrode 13, the operation switch 14 and the temperature control button 15 to set the temperature. The indicator 16 is controlled.

The dummyster 11 detects the room temperature as the room temperature detecting means of the present invention and sends the detected value to the microcomputer 10. The temperature adjustment button 15 is a setter for setting the set temperature as the temperature setting means of the present invention. The set temperature indicator 16 displays the set temperature set by the temperature control button 15.

The microcomputer 10 is connected to the spark electrode 13, the electric motor 31, according to the electrical signals sent from the dummyster 11, the thermocouple 12, the operation switch 14 and the temperature control button l5. 51, the first kettle valve 71, the second kettle valve 72, the proportional control valve 74 and the set temperature indicator 16 is controlled.

In addition, the microcomputer 10 changes the energization amount of the electric motors 31 and 51 and the proportional control valve 74 in seven steps from the weak operation to the strong operation in response to the room temperature and the set temperature during the combustion operation. In addition, the microcomputer 10 drives the FF gas hot air heater 1 by forced "strong" operation, normal operation and rapid operation.

The forced " strong " operation operates the rotational speed of the electric motors 31 and 51 and the energization amount of the proportional control valve 74 to the maximum until the predetermined time elapses after ignition.

Normal operation is the operation of changing the energization amount of the proportional control valve 74 to the first predetermined speed based on the target value (see the graph in FIG. 2) according to the temperature difference between the room temperature and the set temperature (see the graph in FIG. 3). . During normal operation, since the energization amount of the proportional control valve 74 changes at the first predetermined speed, the rotational speed of the electric motors 31 and 51 (controlled by the energization amount to the electric motors 31 and 51) is also determined by the first. Change at a predetermined speed.

In the rapid operation, when the temperature control button 15 is operated, the energization amount of the proportional control valve 74 is larger than the first predetermined speed based on the target value (see the graph in FIG. 2) according to the temperature difference between the room temperature and the set temperature. For example, driving at a second predetermined speed 5 times faster (see graph in FIG. 3). During rapid operation, since the energization amount of the proportional control valve 74 changes at the second predetermined speed, the rotation speeds of the electric motors 31, 51 also change at the second predetermined speed.

Here, in the graph of FIG. 3, the solid line shows rapid operation, and the broken line shows normal operation. T ₁ represents the first holding time (eg, for 10 seconds), and T ₂ represents the second holding time (eg, for 2 seconds).

4 shows a flowchart showing the main control of the microcomputer 10.

First, it is determined whether or not the temperature control button 15 has been operated (step S ₁ ). When the temperature control button 15 is not operated (NO), the room temperature tr is detected (step S ₂ ), the set temperature ts is read out (step S ₃ ), and the room temperature tr The target value (target step) corresponding to the temperature difference from the set temperature ts is calculated (step S ₄ ). Then, it is determined whether or not the energization amount of the proportional control valve 74 is the target value (step S ₅ ). At the target value (YES), control of step S ₁ is performed.

When not a target value in step S ₅ (NO), first determines whether the first holding time (T ₁₎ has elapsed (step S _6), when it is not, and T ₁ has elapsed (NO), step S ₆ Control is performed.

In step S _6, then T ₁ At this time elapses (YES), only the proportional control valve 74, the distribution amount to the step change (step S _7).

Thereafter, the control of step S ₅ is performed.

In step S ₁ , when the temperature control button 15 is operated (YES), the room temperature tr is detected (step S ₈ ), and the set temperature ts is read out (step S ₈ ), The target value according to the temperature difference between the room temperature tr and the set temperature ts is calculated (step S ₁₀ ). Then, it is judged whether or not the current carrying amount of the proportional control valve 74 is the target value (step S ₁₁ ). At the target value (YES), the control of step S ₁ is performed.

In step S ₁₁ , when it is not the target value (NO), it is determined whether the second holding time T ₂ has elapsed. (Step S ₁₂ ). When (T ₂ ) has not elapsed (NO), control of step S ₁₂ is performed.

When (T ₂ ) has elapsed in step S ₁₂ (YES), the amount of energization to the proportional control valve 74 is changed by only one step (step S ₁₃ ). Thereafter, the control of step S ₁₁ is performed.

The FF type gas warm air heater 1 of the present embodiment will be described with reference to FIGS.

When the operation switch 14 is set to the "mouth" side, the "strong" operation is forcibly performed until the FF type gas warm air heater 1 passes a predetermined time. After the forced "strong" operation, according to the temperature difference between the room temperature detected by the dummy computer 11 by the microcomputer 10 and the set temperature set by the temperature control button 15, the gas burner 6 The target value of the combustion amount is calculated.

The target value of the combustion amount of the gas burner 6 is, for example, the fourth stage combustion amount is obtained when the temperature difference ± Δt (for example, 0.375) ° C. between the room temperature tr and the set temperature ts (see the graph in FIG. 2). ). When the temperature difference between the actual temperature and the room temperature becomes larger than ± Δt ° C, the target value of the combustion amount of the gas burner 6 is switched to the first to third stage or the fifth to seventh stage according to the temperature difference between the indoor temperature and the set temperature. .

For example, when the current stage is being operated at the third stage of combustion, if the seventh stage of combustion is obtained as the target value, the amount of energization of the proportional control valve 74 is set after the first holding time (T ₁ = 10 seconds) has elapsed. Increase only one step (see graph in Figure 3).

In this way, when the energization amount of the proportional control valve 74 increases at a rate of one step in 10 seconds, correspondingly, the electric motor 51 of the vibration motor 31 of the convection blower 3 and the combustion blower 5 correspondingly. The amount of energization also increases at a rate of 1 step for 10 seconds. That is, the energization amount of the electric motors 31 and 51 and the proportional control valve 74 increases at a first predetermined speed.

For this reason, the opening degree of the gas piping 75 is gradually increased by the proportional control valve 74, and the gas amount of the fuel gas supplied to the gas burner 6 also increases gently.

Thus, when the temperature control button 15 is not operated, since the combustion amount of the gas burner 6 changes slowly at the 1st predetermined speed, the temperature and air flow amount of the air which flows into the room inside the hot air duct 2 also become slow. To change. Therefore, even if the amount of energization of the proportional control valve 74 is controlled step by step when the room temperature is approaching the set temperature, the amount of energization of the electric motor 31. There are no other steps to and from. Therefore, the energization amount of the electric motors 31 and 51 does not travel between any stage and any other stage. That is, in the energization control of the electric motors 31 and 51, no hunting phenomenon occurs, and therefore the noise is reduced because the rotation speeds of the convection fan 32 and the combustion fan 52 are stabilized.

In addition, it is conceivable that the indoor temperature detected by the dummyster 11 greatly decreases for a moment by causing confusion of the room temperature in one instant. Even in this case, the energization amount of the proportional control valve 74 does not change unless the first holding time elapses as described above. For this reason, when the room temperature is stabilized to the original temperature during the first holding time, the amount of gas supplied to the gas burner 6 does not change. That is, although it is not necessary to raise room temperature, the amount of electricity supplied to the proportional control valve 74 is rapidly increased so that the amount of gas is not changed. For this reason, by maintaining the stable state of the gas burner 6, it can prevent that a room temperature rises significantly more than set temperature.

In addition, when the temperature control button 15 is operated, for example, when the indoor temperature is set at 19.5 ° C. and the set temperature is set at 19 ° C., the microcomputer 10 causes the gas burner 6 to be switched to 22 ° C. The combustion amount of the 7th stage is calculated | required as a target value of the combustion amount of ().

For this reason, since the FF type gas-heated air heater 1 is currently operating in the third stage combustion amount, the energization amount of the proportional control valve 74 is changed by only one stage after the second holding time (T ₂ = 2 seconds) has elapsed. Increase (see graph in FIG. 3).

In this way, when the energization amount of the proportional control valve 74 increases at a rate of one step for 2 seconds, the electric motor 31 of the convection blower 3 and the electric blower 5 of the combustion blower 5 correspond to that. The amount of energization of 51) also increases at a rate of one step for two seconds. That is, the energization amount of the electric motors 31 and 51 and the proportional control valve 74 increases at the 2nd predetermined speed.

As described above, by rapidly operating the FF gas-heated air heater 1, the room temperature can be quickly approached to the set temperature.

That is, when the temperature control button 15 is operated by the user to rapidly increase or decrease the combustion amount of the gas burner 6, the user can increase or decrease the amount of gas supplied to the gas burner 6 rapidly. The desired heating effect can be obtained.

(Variation)

In this embodiment, the rotational speeds of the combustion fan and the convection fan are set in accordance with the energization amount of the proportional control valve. However, the rotational speed of the combustion fan or the convection fan may be set in accordance with the difference between the set temperature and the room temperature.

In the present embodiment, fuel gas is used as fuel, but liquid fuel may be used as fuel.

In this embodiment, the hot air heater is used for the FF gas hot air heater, but the hot air heater may be used for another hot air heater such as a fan heater.

Claims (1)

A warm air duct for directing air to the room, a burner for heating the air passing through the hot air duct by combustion with fuel, a proportional control valve for changing the amount of fuel supplied to the burner according to the amount of energization, and the warm air The temperature setting in the hot air heater comprising a convection blower for generating an air flow to the room in the duct, a temperature setting means for setting the temperature of the room, and a temperature detecting means for detecting the temperature of the room. And a control circuit for gradually changing the energization amount supplied to the proportional control valve on the basis of the set temperature set by the means and the detection temperature detected by the temperature detection means, wherein the control circuit includes the proportional control valve. The amount of electricity supplied to the controller is changed to the first predetermined speed during normal operation, and the temperature setting means is operated. In the hot air heaters, it comprising a step of changing to a second predetermined speed faster than said first predetermined speed if the.