JP2004044852A - Warm air heater having negative ion generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a warm air heater usable as a negative ion generator. <P>SOLUTION: A combustion chamber 6 of a burner 5 is disposed in a draft air duct 2 for communicating the back part with the front part of a frame body 1, an indoor convection fan 3 is mounted on the back side of the frame body 1, and a warm air outlet 4 is mounted on the front side of the frame body 1. Indoor air sucked into the draft air duct 2 by the convection fan 3 increases in temperature and blows off from the warm air outlet 4 into the room. An electrode 8 connected to a high voltage power supply device 7 facing the inside of the draft air duct 2, the electrode 8 is connected to a negative high voltage, the draft air duct 2 wall is connected to a positive high voltage, and generated negative ions are jetted from the warm air outlet 4. A heat ray transmission section 9 is formed in a combustion chamber 6 wall, a red heat body 10 is disposed in the combustion chamber 6, and the electrode 8 is disposed facing the red heat body 10 via the heat ray transmission section 9. The electrode 8 is kept at high temperature by the heat ray radiated from the red heat body 10, and cotton dust flowing through the draft air duct 2 is carbonized by heat of the electrode 8, blown away by air flow, and hence prevented from adhering to the electrode 8. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
[Industrial applications]
The present invention relates to a hot air heater that can be used as a negative ion generator throughout the year.
[0002]
[Prior art]
The negative ion generator positively charges the wall of the air passage of the blower, and arranges an electrode connected to the negative output toward the inside of this air passage, and applies a high voltage between the wall of the air passage and the electrode. Then, the air near the electrode is negatively ionized by corona discharge, and when the air flow by the blower passes near the electrode, the negatively ionized air is blown into the room and new air is continuously ionized near the electrode by continuous negative ionization. This is to blow out negative ions.
[0003]
Then, the generated negative ions disappear by touching the positive ions that existed in the air in the ventilation path in advance, and disappear by touching the wall surface of the positively charged ventilation path. Even after blowing out from the outlet, it disappears by touching positive ions in the air, and in general, the amount of negative ions near the waterfall generated by the Leonard effect in the natural state as a guide, the front of the outlet It is designed so that 1 to 20,000 or more negative ions can be obtained in one meter.
[0004]
If an electrode is provided in a place where there is air flow, it functions as a negative ion generator, so a negative ion generator is configured in the air passage of the air purifier and it has already been put into practical use as an air purifier with a negative ion generator. Have been. For this reason, as described above, an indoor convection fan is provided in the frame of the warm air heater, and there is an air passage through which air is sent by the indoor convection fan. By applying a high voltage between the charged ventilation path wall and the electrode connected to the negative output, a negative ion generator can be configured.
[0005]
[Problems to be solved by the invention]
However, when the negative ion generator is configured in the air passage of the hot air heater instead of the air purifier, it is inevitable that dust adheres to the electrode connected to the negative output protruding into the air passage, If a large amount of dust adheres to the electrodes and the dust ignites with the heat of the heater, the heater may cause a fire. For this reason, in the related art, it is not actually commercially available to configure the negative ion generator by directly using the air passage of the hot air heater, even if it exists as an idea.
[0006]
Since it is quite dangerous to construct a negative ion generator using a ventilation path that produces warm air in the frame of the heater, a second ventilation path different from the ventilation path in the frame of the heating machine is dangerous. Further, a structure in which a dedicated air passage is formed in the air passage and the electrode of the negative ion generator is installed in the new air passage has been studied. With this structure, the ventilation path and the negative ion flow path are independent, so the negative ion generator can be operated safely even during heating, and the negative ion generator can be used throughout the year. The path for effective use has been opened.
[0007]
However, since this structure merely attaches a single negative ion generator to the heater, the manufacturing cost can hardly be reduced, and the actual selling price of the mass-produced negative ion generator has recently decreased. Therefore, it may be cheaper to purchase the heater and the negative ion generator separately, and it is not possible to take advantage of the fact that the heater and the negative ion generator are incorporated in the same frame.
[0008]
On the other hand, it is known that in heaters that use fuel combustion, a large amount of positive ions and negative ions are mixed in the combustion flame in a plasma state. The nature of this flame is used for flame detection by flame rod. In the case of a heater called a fan heater that sends out a large amount of positive ions and negative ions contained in this combustion flame together with the combustion gas to the air passage, if the air passage is equipped with an electrode connected to the negative output, it is realized If possible, the negative ions generated in the vicinity of the electrode are immediately linked to the positive ions in the combustion gas and disappear efficiently, so the number of positive ions blown out from the hot air outlet decreases and the difference from the number of negative ions is reduced. The number of negative ions will increase.
[0009]
[Means for Solving the Problems]
According to the present invention, a negative ion generator is configured by using an air passage of a hot air heater, and an air passage 2 that connects a back portion of the frame 1 and a front portion of the frame 1 is provided in the frame 1. An indoor convection fan 3 is mounted on the back side of the frame 1 of the air passage 2, and a hot air outlet 4 is mounted on the front side of the frame 1 of the air passage 2, and a burner 5 is installed in the air passage 2. The room air blown into the air passage 2 by the convection fan 3 has a high temperature and is blown into the room from the hot air outlet 4, and the high-pressure power supply device is viewed in the air passage 2. 7 is connected to the electrode 8 at a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage, and the negative ions generated from the electrode 8 are blown out from the hot air outlet 4 by hot air heating. In the machine, a heat ray transmitting portion 9 is formed on the wall of the combustion chamber 6, and the heat ray transmitting portion 9 is The combustion chamber 6 arranged glowing member 10, the electrode 8 is characterized by being disposed to face the glowing member 10 through the heat ray transmitting unit 9.
[0010]
Further, since the exhaust opening 11 is provided on the wall of the combustion chamber 6 and the electrode 8 is arranged to face the exhaust opening 11, the electrode 8 can be maintained at a high temperature by the heat of combustion of the burner 5.
[0011]
Further, an exhaust opening 11 is provided in the wall of the combustion chamber 6, the electrode 8 is arranged to face the exhaust opening 11, and the electrode 8 places the red-hot body 10 in the combustion chamber 6 looking through the exhaust opening 11. The arrangement allows the electrode 8 to be maintained at a high temperature even if it is separated from the exhaust opening 11.
[0012]
The electrode 8 is mounted in the air passage 2 looking into the combustion chamber 6 where the temperature is high, and a wind shield 12 is disposed in the air passage 2 closer to the indoor convection fan 3 than the electrode 8. By suppressing the airflow near the electrode 8, the negatively ionized gas near the electrode 8 can be blown out from the hot air outlet 4 with only slight attenuation.
[0013]
Further, an exhaust opening 11 is provided in the wall of the combustion chamber 6, the electrode 8 is arranged to face the exhaust opening 11, and a windshield 12 is provided on the indoor convection fan 3 side of the exhaust opening 11 and the electrode 8. Since the high-temperature combustion gas is diffused in the vicinity of the electrode 8 by the windshield 12, the electrode 8 can be maintained at a high temperature.
[0014]
In addition, the windshield 12 provided between the electrode 8 and the indoor convection fan 3 is provided with a ventilation port 13 for the airflow from the indoor convection fan 3 to the electrode 8, so that the ventilation hole 13 is provided around the electrode 8. Since the air from the indoor convection fan 3 flows, negative ions can be efficiently generated even when the heater is not used.
[0015]
Further, a filter 14 made of a wire mesh or the like is attached to the suction side of the indoor convection fan 3 and an air inlet 14a is provided on a side wall between the filter 14 and the indoor convection fan 3 to flow into the negative ion generator. Cotton dust can be suppressed.
[0016]
[Action]
The negative ion generator arranges the electrode 8 in the air passage 2 having a forced air flow, and applies a positive high voltage to the air passage 2 side and a negative high voltage to the electrode 8 side. Negatively ionizes the air near. The negative ionized air can be blown into the room by the airflow of the indoor convection fan 3 to form a negative ion generator. Therefore, not only the dedicated negative ion generator but also the electrode 8 can be connected to the air passage 2 of the hot air heater. And can also be used as a negative ion generator.
[0017]
Since indoor air flows through the air passage 2 which is indispensable for the negative ion generator, it is inevitable that dust will flow along with the air blown into the air passage 2, and when the air is used also as a heater. Dust adheres to the vicinity of the electrode 8. Since the electrode 8 of the present invention is always disposed at a position where fresh air flows while being heated by the heat source, the dust attached to the electrode 8 is carbonized by the heat before being accumulated in a large amount and is blown off by the air flow. The dust does not accumulate so much as to cause the problem.
[0018]
【Example】
The present invention will be described with reference to an embodiment in which a heater using petroleum fuel and a negative ion generator are used as shown in the figure. 1 is a frame of the heater, and 5 is a burner which is arranged in the frame 1 to constitute a heat source. Reference numerals 6 denote combustion chambers disposed above the burner 5 and through which combustion flame and combustion gas are sent. Reference numeral 2 denotes an air passage formed to penetrate from the back to the front of the frame 1, 3 denotes an indoor convection fan provided on the inlet side of the air passage 2 near the back of the frame 1, 4 denotes an outlet of the air passage 2 , A hot air outlet forming a front opening of the frame 1, 15 is a louver attached to the hot air outlet 4, 15 a is a guard, and the upper part of the burner 5 and the combustion chamber 6 are disposed in the air passage 2. I have.
[0019]
Reference numeral 16 denotes a heater that also serves as an ignition for raising the burner to a combustible temperature, 17 denotes a combustion fan that supplies combustion air to the burner 5, 18 denotes a fuel pump that supplies fuel to the burner 5, 19 denotes a combustion fan 17, a fuel pump 18 and the like. Is a controller for controlling various electric components, and 20 is an operation unit of the heater. When the heater is started according to an instruction of the operation unit 20, the controller 19 energizes the heater 16 to bring the burner 5 to a combustible temperature. Then, the combustion fan 17 and the fuel pump 18 are driven. The petroleum fuel is ignited in the burner 5 and starts burning, and is completely burned in the combustion chamber 8.
[0020]
The oil heater of the embodiment shown in FIG. 1 is an intake / exhaust type heater, in which reference numeral 21 denotes a heat exchange chamber disposed in the air passage 2 together with the combustion chamber 6, and reference numeral 22 designates a combustion gas from the heat exchange chamber 21 to the outside. The exhaust pipe is an exhaust pipe to be discharged, and the combustion gas exiting the combustion chamber 6 passes through the heat exchange chamber 21 and is exhausted to the outside by the exhaust pipe 22. The oil heater of the embodiment shown in FIG. 2 is of a type that emits a combustion gas called a fan heater into a room. Reference numeral 11 denotes an exhaust opening provided on an upper wall constituting a wall surface of the combustion chamber 6. The exhaust opening 11 is open in the air passage 2, and the combustion gas is sent to the air passage 2.
[0021]
In the above-described oil burner, when the indoor convection fan 3 is operated, the indoor air is blown into the air passage 2, and the indoor air exchanges heat with the combustion chamber 6 and the heat exchange chamber 21. Further, in the embodiment of FIG. Mixing with the high-temperature combustion gas sent from the exhaust opening 11, the temperature of the room air in the air passage 2 is increased, and the air is blown into the room from the hot air outlet 4 as hot air.
[0022]
The air-intake / exhaust type heater of the embodiment shown in FIG. 1 is a heat-radiation type heater having a large front opening constituting the hot air outlet 4 of the frame 1, and 10 is located in the combustion chamber 6. 9 is a heat ray permeable portion which constitutes the side wall of the combustion chamber 6 with heat-resistant glass or the like. 23 is located on the side and the back of the combustion chamber 6 and has a side end near the front opening of the frame 1. The combustion flame and the combustion gas of the burner 5 heat the red hot body 10 in the combustion chamber 6, and the heat rays radiated from the red hot body 10 are transmitted through the heat ray transmitting portion 9 on the side wall of the combustion chamber 6. And radiates forward from the front opening of the frame 1, and heat rays directed to the sides and the back are reflected by the reflector 23 and radiated forward from the front opening of the frame 1 to heat.
[0023]
Reference numeral 8 denotes an electrode whose tip is located in the air passage 2. Reference numeral 7 denotes a high-voltage power supply that is attached to the frame 1 and grounds the plus side to the frame 1. The negative output of the high-voltage power supply 7 is applied to the electrode 8. Connected. When the high voltage power supply 7 is energized, it is grounded to the frame 1 and the wall of the air passage 2 becomes positive, and the electrode 8 becomes negative, so that corona discharge is started and the air near the electrode 8 is ionized negatively. When the indoor convection fan 3 is operated, the room air blows the negative ionized air near the electrode 8 together with the warm air from the warm air outlet 4 into the room, thereby forming a negative ion generator.
[0024]
Although the present invention aims to serve both as a negative ion generator and a heater, an air conditioner including an air conditioner or an air purifier, which has a negative ion generator in its air passage, has already been put to practical use. . However, a device in which a negative ion generator is configured by using an air passage of a hot air heater as in the present invention has not been put to practical use. The reason for this is that the electrodes are protruded from the air passage, so that the dust blown into the air passage along with the air flow accumulates on the electrodes and accumulates. There is no guarantee that workers will perform cleaning on a regular basis. For this reason, existing equipment incorporating a practically used negative ion generator implements maintenance-free electrodes by installing a powerful filter.However, such a powerful filter is used in a heater with a heat source. If the filter is clogged, if the clogging of this filter occurs, the cooling air flow inside the frame cannot be secured, and there is a risk of fire due to abnormal heating of the frame, so a filter with a rough filter is used. I have. Because of such a filter, in an actual heater, dust easily enters the air passage, and it is inevitable that dust adheres to the electrode. If a large amount of dust adheres to the electrode and the dust is ignited by the heat of the burner, a large accident such as a fire may occur.
[0025]
In the present invention, when a negative ion generator and a heater that is not used in the summer are integrated into the same frame 1 for integration, the mounting position of the electrode 8 in the air passage 2 is limited for a long time. The occurrence of trouble could be prevented even if the use was continued. That is, in the first embodiment, in the heater in which the heat ray transmitting portion 9 is formed on the wall of the combustion chamber 6, the red hot body 10 is disposed in the combustion chamber 6 looking into the heat ray transmitting portion 9 and attached to the wall of the air passage 2. The position of the glow body 10 and the position of the electrode 8 are specified so that the electrode 8 is located at a position facing the glow body 10 via the heat ray transmitting portion 9. In order to blow out the negative ions from the hot air outlet 4, an air flow is required. In the heater of the embodiment shown in FIG. 1 in which the electrode 8 is attached to the lower part of the air passage 2, 23a is located at the back of the combustion chamber 6. This is a ventilation notch provided on the upper part of the reflection plate 23 that the user wants, and the wind of the indoor convection fan 3 can be blown toward the electrode 8 from the ventilation notch 23a.
[0026]
Further, in the second embodiment, in a heater having an exhaust opening 11 in the wall of the combustion chamber 6, the electrode 8 attached to the wall of the air passage 2 is specified so as to be located at a position facing the exhaust opening 11. In addition, since the exhaust opening 11 provided in the general combustion chamber 6 is formed in the upper part of the combustion chamber 6, the electrode 8 is attached downward from the top plate of the air passage 2.
[0027]
At the position of the electrode 8 attached in this way, it is intended that this electrode 8 is in a state of being strongly heated by the combustion heat of the burner 5, and in the first embodiment, the radiation of the glowing red-hot body 10 is achieved. Upon receiving heat, and in the second embodiment, receiving the heat of the combustion gas released from the exhaust opening 11, the dust is heated to a temperature at which it is carbonized or oxidized in a short time even if it adheres, and is preferably red-hot. The electrode 8 is mounted at a position where the electrode 8 is heated more.
[0028]
For this reason, the indoor air is blown into the air passage 2 by the indoor convection fan 3. Even if the dust enters the air flow and tries to adhere to the electrode 8, the dust is immediately carbonized or heated by the heat of the burner 5. Since it is oxidized and dissipated, it is no longer possible to suddenly start igniting combustion with a large amount of dust attached. Also, if only the function of the negative ion generator is used in the summer, dust is attached to the electrode 8 when the heater is started to be used in the winter. As the temperature increases, the dust is gradually carbonized or oxidized, and the dust is blown away and disappears before the electrode 8 becomes red hot. When the dust is blown off, the air in each part of the heater and the air passage 2 is still at a low temperature. Has subsided and normal heater use can begin.
[0029]
Further, in the third embodiment, the exhaust opening 11 provided in the wall of the combustion chamber 6 can radiate not only the combustion gas but also the heat rays from the exhaust opening 11 and functions as the heat ray transmitting portion 9. A red-hot body 10 is arranged in a combustion chamber 6 looking into the section (part), and an electrode 8 is attached to a top plate of the air passage 2 looking into the red-hot body 10.
[0030]
With such a structure, since the electrode 8 is heated by the hot wire together with the high-temperature combustion gas, the electrode 8 is heated by the hot wire even if the distance between the top plate of the air passage 2 and the exhaust opening 11 is slightly apart, for example. The temperature of the electrode 8 quickly rises and works effectively when the dust is carbonized or oxidized and escapes.
[0031]
As described above, the present invention does not disperse the dusts attached to or about to be attached to the electrodes 8 by carbonizing or oxidizing them by maintaining the electrodes 8 at a temperature high enough to glow the electrodes 8 with the heat of combustion of the burners 5. However, the electrode 8 is a portion that generates only negative ions, and is installed in a place where the ventilation airflow of the indoor convection fan 3 cannot be expected, for example, in the combustion chamber 6 because the electrode 8 becomes red hot. Occasionally, even if the negative ion generator is operated alone, a large amount of negative ions cannot be blown out from the hot air outlet 4, so that the mounting position of the electrode 8 deteriorates the ability of generating negative ions. Not be.
[0032]
Furthermore, since the warm air of the heater has a function of effectively sending out the heat of the burner 5 from the inside of the frame 1 to the room, a considerably strong wind speed is required. When used only as a negative ion generator in summer, the wind speed of the indoor convection fan 3 can be suppressed. However, in the case of a heater, a wind speed corresponding to the calorific value of the burner 5 is required. When the negative ions generated from the air are blown onto the wall of the air passage 2 or the louver 15, there is a possibility that the positive ions of the frame body 1 may disappear by touching the positive ions and the amount of negative ions may not be obtained as expected.
[0033]
The fourth embodiment of the present invention relates to a structure for effectively generating negative ions, and reference numeral 12 denotes a wind shield attached to the air passage 2 closer to the indoor convection fan 3 than the electrode 8. The wind shield 12 prevents the wind of the indoor convection fan 3 from blowing through the vicinity of the electrode 8. In the embodiment of FIG. 1, the reflector 23 functions as the wind shield 12. The wind of the indoor convection fan 3 bypasses the wind shield plate 12 and reaches the vicinity of the electrode 8, so that the wind speed is weakened. Could flow toward the hot air outlet 4 in the central portion of the air passage 2 away from the wall of the air passage 2, and the amount of negative ion attenuation could be suppressed.
[0034]
In the fifth embodiment, an exhaust opening 11 is provided in the wall of the combustion chamber 6, and the electrode 8 is arranged so as to face the exhaust opening 11, so that the electrode 8 is heated by the combustion gas. Since the combustion gas contains substantially the same amount of positive ions and negative ions generated by the combustion flame, when the wind shield plate 12 is arranged on the windward side of the electrode 8, the indoor convection is caused by the wind shield plate 12. Since the wind of the fan 3 is suppressed, the combustion gas is easily diffused around the electrode 8.
[0035]
If the combustion gas containing a large amount of ions diffuses around the electrode 8 to which a negative high voltage is applied, the negative charge of the electrode 8 due to the high voltage is combined with the positive ions in the combustion gas and disappears. The hot air blown out from the hot air outlet 4 contains a large amount of negative ions contained in the combustion gas. When the positive ions in the combustion gas are reduced and negative ions are left in this way, the number of effective negative ions, which is the difference between the number of positive ions and the number of negative ions blown out from the hot air outlet 4, is determined by the number of the negative ion generator alone. It is possible to obtain a larger number of negative ions than in operation.
[0036]
As described above, the function of the wind shield plate 12 is an effective structure for a heater that cannot reduce the air volume of the indoor blower fan 3, but when used as a negative ion generator, the air volume is too small to obtain the expected number of negative ions. There may not be. For this reason, in the sixth embodiment, reference numeral 13 denotes a ventilation port provided in the wind shield plate 12 in the direction of the electrode 8, and the air flow from the indoor convection fan 3 toward the electrode 8 can be formed. Even if the wind speed of 3 is reduced, a constant air flow can be secured around the electrode 8, the gas containing negative ions diffused in the vicinity of the electrode 8 is efficiently led to the hot air outlet 4, and the negative ions pass through the air passage 2. The amount that disappears by touching the wall can be minimized. Of course, the ventilation hole 13 works effectively even when it is used as a heater, and can guide a large amount of negative ions in the vicinity of the electrode 8 to the hot-air outlet 4.
[0037]
Moreover, the heater provided with the burner 5 in the frame 1 needs an airflow in the air passage 2 as described above, and cannot prevent intrusion of dust. However, it is very effective to minimize the intrusion of dust for the negative ion generator. In the seventh embodiment, 14 is provided so as to directly block the airflow toward the indoor convection fan 3. The filter 14 a is an air inlet opening on the side wall of the air passage 2 between the filter 14 facing the indoor convection fan 3 and the indoor convection fan 3.
[0038]
With such a structure, the indoor convection fan 3 sucks most of the air from the filter 14, and the dust in the air is collected by the filter 14, and the dust attached to the electrode 8 can be reduced. . When a large amount of dust adheres to the filter 14 and the flow path resistance becomes large, air flows in from the side air inlet 14a instead of the filter 14, and the air passage 2 as a heater is formed. Airflow can be secured. Even if dust enters and adheres to the electrode 8 due to this air flow, the amount of dust becomes much smaller than when the filter 14 is not provided.
[0039]
【The invention's effect】
As described above, in the present invention, the glowing body 10 is disposed in the combustion chamber 6 related to the heat source of the heater, and the electrode 8 is opposed to the glowing body 10 via the heat ray transmitting portion 9 of the combustion chamber 6 wall. The temperature of the electrode 8 becomes high due to the heat rays radiated from the body 10 and the dust cannot flow onto the electrode 8 even if the dust flows through the air passage 2. 8 could be directly arranged.
[0040]
Further, when the exhaust opening 11 is provided in the wall of the combustion chamber 6 to discharge the combustion gas to the air passage 2, the electrode 8 is attached to the air passage 2 opposed to the exhaust opening 11, so that not only the heat radiation from the combustion chamber 6 but also Since the electrode 8 can be heated and maintained at a high temperature also by the combustion gas of the burner 5, an effect is obtained that the dust cannot flow onto the electrode 8 even if the dust flows through the air passage 2.
[0041]
Further, when an exhaust opening 11 is provided in the wall of the combustion chamber 6 to discharge the combustion gas to the air passage 2 and the electrode 8 is attached to the air passage 2 opposed to the exhaust opening 11, the combustion chamber 6 contains a red hot body. If the electrode 8 is arranged and opposed to the electrode 8, the electrode 8 is heated by the combustion gas and the heat of the red hot body 10 radiated from the exhaust opening 11 constituting the heat ray transmitting portion. Even if the dust is flowing, it can be maintained at a high temperature, and even if the dust flows in the air passage 2, the dust cannot adhere to the electrode 8.
[0042]
Further, in the air passage 2 closer to the indoor convection fan 3 than the electrode 8 attached to the air passage 2, the wind shield 12 for suppressing the air flow near the electrode 8 is arranged. The air flow is no longer blown, and the negatively ionized gas near the electrode 8 reaches the hot air outlet 4 in a state where the gas hardly touches the wall surface of the air passage 2, so that the amount of attenuation is small and hot air containing a large amount of negative ions is blown out. Now you can do it.
[0043]
The electrode 8 is attached to the air passage 2 facing the exhaust opening 11 provided on the wall of the combustion chamber 6, and the wind shield 12 is arranged in the air passage 2 closer to the indoor convection fan 3 than the electrode 8. Since the combustion gas discharged from the combustion gas 11 can be diffused around the electrode 8, the electrode 8 can be maintained at a high temperature, and the positive ions contained in the combustion gas are eliminated by the electrode 8. Could be efficiently blown out from the warm air outlet 4.
[0044]
In addition, the windshield 12 disposed in the airflow path 2 closer to the indoor convection fan 3 than the electrode 8 attached to the airflow path 2 is provided with a ventilation port 13 that creates an airflow toward the electrode 8. Since the air blown by the indoor convection fan 3 always flows, negative ions near the electrode 8 can be efficiently blown out of the hot air outlet 4 particularly when the heater is not used.
[0045]
Further, a filter 14 made of a wire mesh or the like is attached to the suction side of the indoor convection fan 3 and an air inlet 14 a is provided on a side wall between the filter 14 and the indoor convection fan 3. The dust contained therein can be collected, making it difficult for the dust to adhere to the electrode 8 even when the negative ion generator is used alone, and when a large amount of dust adheres to the filter 14, air is blown from the air inlet 14a. Since the air is sent to the air passage 2, an air flow that does not increase the temperature of the frame 1 of the heater can be secured, and the dual-purpose device can be used with security.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a heater showing an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a heater showing another embodiment of the present invention.
[Explanation of symbols]
REFERENCE SIGNS LIST 1 frame 2 ventilation path 3 indoor convection fan 4 hot air outlet 5 burner 6 combustion chamber 7 high-voltage power supply 8 electrode 9 heat ray transmission part 10 red heat body 11 exhaust opening 12 windshield 13 ventilation hole 14 filter 14a air inlet

Claims (7)

An air passage 2 is provided in the frame 1 to communicate the back of the frame 1 and the front of the frame 1, and an indoor convection fan 3 is provided on the back side of the frame 1 of the air passage 2. A hot air outlet 4 is mounted on the front side of the frame 1 of the second embodiment, a combustion chamber 6 of a burner 5 is arranged in the air passage 2, and the room air blown into the air passage 2 by the convection fan 3 has a high temperature. As it blows out from the warm air outlet 4 into the room,
An electrode 8 connected to the high-voltage power supply 7 is disposed in the air passage 2 and the electrode 8 is connected to a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage. In the hot air heater that blows out the negative ions from the hot air outlet 4,
A heat ray transmitting portion 9 is formed on the wall of the combustion chamber 6, and a red hot body 10 is disposed in the combustion chamber 6 looking into the heat ray transmitting portion 9, and the electrode 8 is connected to the red hot body 10 through the heat ray transmitting portion 9. A warm air heater equipped with a negative ion generator arranged side by side. An air passage 2 is provided in the frame 1 to communicate the back of the frame 1 and the front of the frame 1, and an indoor convection fan 3 is provided on the back side of the frame 1 of the air passage 2. A hot air outlet 4 is mounted on the front side of the frame 1 of the second embodiment, a combustion chamber 6 of a burner 5 is arranged in the air passage 2, and the room air blown into the air passage 2 by the convection fan 3 has a high temperature. As it blows out from the warm air outlet 4 into the room,
An electrode 8 connected to the high-voltage power supply 7 is disposed in the air passage 2 and the electrode 8 is connected to a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage. In the hot air heater that blows out the negative ions from the hot air outlet 4,
An exhaust opening 11 is provided in a wall of the combustion chamber 6, and the electrode 8 is arranged to face the exhaust opening 11, wherein a negative ion generator is juxtaposed. An air passage 2 is provided in the frame 1 to communicate the back of the frame 1 and the front of the frame 1, and an indoor convection fan 3 is provided on the back side of the frame 1 of the air passage 2. A hot air outlet 4 is mounted on the front side of the frame 1 of the second embodiment, a combustion chamber 6 of a burner 5 is arranged in the air passage 2, and the room air blown into the air passage 2 by the convection fan 3 has a high temperature. As it blows out from the warm air outlet 4 into the room,
An electrode 8 connected to the high-voltage power supply 7 is disposed in the air passage 2 and the electrode 8 is connected to a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage. In the hot air heater that blows out the negative ions from the hot air outlet 4,
An exhaust opening 11 is provided in the wall of the combustion chamber 6, the electrode 8 is arranged to face the exhaust opening 11, and the red body 10 is arranged in the combustion chamber 6 through which the electrode 8 looks through the exhaust opening 11. A hot air heater equipped with a negative ion generator. An air passage 2 is provided in the frame 1 to communicate the back of the frame 1 and the front of the frame 1, and an indoor convection fan 3 is provided on the back side of the frame 1 of the air passage 2. A hot air outlet 4 is mounted on the front side of the frame 1 of the second embodiment, and a combustion chamber 6 of a burner 5 is disposed in the air passage 2. As it blows out from the warm air outlet 4 into the room,
An electrode 8 connected to the high-voltage power supply 7 is disposed in the air passage 2 and the electrode 8 is connected to a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage. In the hot air heater that blows out the negative ions from the hot air outlet 4,
The electrode 8 is mounted in the air passage 2 looking into the combustion chamber 6 where the temperature is high, and a wind shield 12 is disposed in the air passage 2 closer to the indoor convection fan 3 than the electrode 8. A hot air heater equipped with a negative ion generator, which is characterized by suppressing airflow. An air passage 2 is provided in the frame 1 to communicate the back of the frame 1 and the front of the frame 1, and an indoor convection fan 3 is provided on the back side of the frame 1 of the air passage 2. A hot air outlet 4 is mounted on the front side of the frame 1 of the second embodiment, a combustion chamber 6 of a burner 5 is arranged in the air passage 2, and the room air blown into the air passage 2 by the convection fan 3 has a high temperature. As it blows out from the warm air outlet 4 into the room,
An electrode 8 connected to the high-voltage power supply 7 is disposed in the air passage 2 and the electrode 8 is connected to a negative high voltage, and the wall of the air passage 2 is connected to a positive high voltage. In the hot air heater that blows out the negative ions from the hot air outlet 4,
An exhaust opening 11 is provided in the wall of the combustion chamber 6, the electrode 8 is disposed so as to face the exhaust opening 11, and a windshield 12 is provided on the indoor convection fan 3 side of the exhaust opening 11 and the electrode 8. A hot air heater provided with a negative ion generator, wherein a high-temperature combustion gas is diffused near the electrode 8 by the wind shield 12. The minus of claim 4 or 5, wherein the wind shield (12) provided between the electrode (8) and the indoor convection fan (3) is provided with a ventilation port (13) for an air flow from the indoor convection fan (3) to the electrode (8). A warm air heater equipped with an ion generator. 7. A filter according to claim 1, wherein a filter made of a wire mesh or the like is attached to a suction side of the indoor convection fan, and an air inlet is provided on a side wall between the filter and the indoor convection fan. A hot air heater equipped with the negative ion generator according to any of the above.

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