KR940004176B1 - Hot air flow space heater - Google Patents

Abstract

At the time of changing the discharge of air from a frontward discharge port (5) to an upper discharge port (4), the rotation speed of a convection type blower (18) is increased by delaying from the closure of the frontward discharge port (5) due to a damper (21). In a ventilation structure in which the direction of air oriented from the convection type blower (18) to the upward discharge port (4) is rectilinear and a flow path resistance is small, it is possible to reduce the noise generated. At the time of changing the discharge from the upward discharge port (4) to the front discharge port (5), the rotation speed of the convection type blower (18) is adjusted to the driving state of a combustion type blower (10), and thereafter the front discharge port (5) is opened by the damper (21).

Description

Warm air heating

1 and 2 are longitudinal sectional views respectively showing main parts of the gas heating apparatus of one embodiment of the present invention.

3 is a broken front view of the gas heating apparatus.

4 is an enlarged perspective view of the main portion.

5 is a block diagram showing control means.

6 to 9 are longitudinal cross-sectional view of the gas hot air heating apparatus of another embodiment of the present invention.

10 is a sectional view showing a modification of the damper.

* Explanation of symbols for main parts of the drawings

1 body case 4 upward outlet

5: front outlet 18: convection blower

31: temperature control means

The present invention relates to a warm air heating device that is provided so as to selectively open and close all of these air outlets by providing an all-broadcast outlet and an ordinary broadcast outlet.

In the conventional hot air heater, a discharge port is formed on the front surface of the main body case, and the heat from the heat generating source is warmed by the blower in front of the main body by the blower, and is forced to be supplied to the room. This is because the warm air heater is installed on the floor, such as on the floor, and the warm air is sent out to the lower part of the room. Therefore, the temperature distribution of the room is good, but the warm air is lighter and moves upwards. By staying, the temperature distribution tends to be poor.

The present invention has been made in view of the above circumstances, and the object thereof is to selectively open and close all broadcasting exits and ordinary broadcasting exits, and to convert the indoor broadcasting exits to facilitate the convection of indoor air so that warm air is indoors. It is possible to provide a warm air heating device which does not stay in the upper portion of the and exhibits an excellent effect of further promoting the uniformity of the temperature distribution.

The present invention relates to an all-broadcast exit and a phase-broadcast exit selectively transformed by a damper, a blower installed to supply wind from the all-broadcast exit and a phase-broadcast exit, and at least all of the front and exit broadcast exits. In the warm air heating device having a heat source for making the wind from the outlet to the warm air to supply a larger amount of air to the outside through the upper broadcasting exit at the time of opening the upper broadcasting exit than from the static broadcasting exit. Control means for converting the damper by increasing the rotational speed of the blower after the end of the conversion of the damper when the conversion to the upper broadcasting exit, and the conversion of the damper by strengthening the rotational speed of the blower when converting from the upper broadcasting exit to all broadcast exits To configure.

After the start of the conversion of the damper from the all-broadcast exit to the up-broadcast exit, a delay of about 2 to 3 seconds is made to increase the number of revolutions of the convection blower, and at the same time, At the time of conversion, the damper is converted by delaying a time of about 2 to 3 seconds after starting the adjustment at the rotational speed according to the set state of the temperature adjusting means.

After detecting the end of the conversion of the damper from the all-broadcast exit to the up-broadcast exit, the rotation speed of the convection blower is increased, and at the time of the conversion from the top-broadcast exit to the all-broadcast exit, The damper is switched after detecting the end of adjustment to the rotational speed.

According to the present invention configured as described above, the conversion of all broadcast exits and the phase broadcast exit is performed to promote the convection of indoor air by opening the phase broadcast exit, so that warm air does not stay in the upper part and the temperature distribution is further improved. Promote

In addition, since the number of revolutions of the convection blower is increased after the completion of the conversion from the all-broadcast exit to the normal-broadcast exit, the large air volume does not come out of the all-broadcast outlet, and thus, the air volume is temporarily released to remove the discomfort. In the case of the conversion from the upper broadcasting exit to the all broadcasting exit, the rotation speed of the convection blower is adjusted to the rotation speed of the small wind volume rather than the wind speed at the time of the upper broadcasting, and after the adjustment is completed, the air outlet is operated so as to change the blowing speed. There is no discomfort felt by temporarily holding.

Next, an embodiment in which the present invention is applied to a gas warm air heating apparatus will be described with reference to FIGS. First, in FIGS. 1 to 3, 1 is a main body case of a flat box shape, and an duct 2 having an open top is disposed inside. 3 is an intake grille formed on the rear surface of the main body case 1, 4, 5 is a top broadcast exit and all-broadcast exit formed adjacent to each other on the upper surface and the upper front of the main body case 1, 6b is the grill (3) And a hot air passage for communicating the broadcast broadcast exit 4 and the all broadcast exit 5 with each other.

6 is a box arranged in the duct 2, and the inside is made into the mixing chamber 6a, and the porous ceramic burner plate 7 is attached to the upper opening part as a heat generating part. 8 is a guide portion provided to surround the upper portion of the ceramic burner plate 7, 9 is provided between the guide portion 8 and the duct 2, and a hole 9a for inlet of the secondary air is formed in the outer surface. One guide duct. 10 is a combustion blower, which consists of a scroll casing 11 and a fan 13 driven by a motor 12. In this combustion blower 10, the scroll casing 11 communicates a bell mouse (not shown) with the outside air, and connects a discharge port (not shown) into the mixing chamber 6a. 14 is a nozzle, the injection side of which is connected to the mixing chamber 6a via the trumpet-shaped guide tube 15, and the other end passes through the proportional valve PH in the middle, and supplies fuel via the supply pipe 16. Derived from a gas source (not shown).

17 is a transverse fan of the convection blower 18, which is disposed in a horizontal state into the hot air passage 6b, and is driven by the motor 19. As shown in FIG.

20 is a horizontal pivot shaft of the transducer tool, which is rotatably supported at the corners of the upper broadcast outlet 4 and the all-broadcast outlet 5 in the main body case 1.

21 is a damper formed in a thin and thin rectangular shape by an elastic member such as a metal, which is selectively opened and closed by the room temperature detection unit Rt according to the room temperature. The upper side part is fixed to the rotation shaft 20, and the pin part 21a is integrally formed in the lower side part. 22 is a gear motor positioned in parallel with the damper 21, which has a well-known built-in speed reduction mechanism, and is installed such that the output shaft 23 protrudes outward through the speed reduction mechanism. The second end of the first link 24 is fixed to the output shaft 23, and one end of the second link 24 is rotatably supported at the other end of the first link 24. The second link 25 is formed to have a central portion of the corrugation by the leaf spring, and elastically stretched in the longitudinal direction to close the sealing by alternately elastically contacting the discharge port with the impact relaxation action of the damper 21. 26 is a third link, one end of which is fixed to the pivot shaft 20 and the other end of which is rotatably supported by an end of the second link 25. As shown in FIG. 4, the magnet 27 is fixed to the second link 25, and the magnet 27 has the conversion end detection unit described later (in the state where the all-broadcast outlet 5 is closed by the damper 21). It is opposed to the guide switch 28 which acts as 37). At the time of pre-broadcasting, the damper 21 spaces the fin part 21a from the front end b of the warm air passage 6b by elastic contact with the rear end a, as indicated by solid lines in FIGS. 1 and 2. The outlet 4 is closed and the all-broadcast outlet 5 is opened. Then, on the burner plate 7, the flame detection thermocouple 29 and the ignition spark electrode 30 are disposed in opposing states.

Next, the operation of the configuration will be described according to the fifth block diagram in which the limiting means is indicated. When the power switch (not shown) is turned on, the combustion blower 10 is first constructed, and the fan 13 is rotated to supply external air from the scroll casing 11 into the mixing chamber 6a. At this time, the intake air amount is suitable for pre-gassing, and the gas amount suitable for this intake air flows from the gas source through the supply pipe 16, the proportional valve PH, the nozzle 14, and the guide pipe 15 in order. Dispersed in 6a). As a result, a mixed gas is generated in the mixing chamber 6a and ignited by the spark electrode 30 at the time when the burner plate 7 passes from below to above, thereby generating a flame. As a result, output is generated from the thermocouple 29, and the combustion blower 10 is in a controlled state. Here, the opening degree of the proportional valve PH is controlled by the set value by the temperature regulating means 31 and the room temperature detection part Rt, and the combustion air is appropriately controlled through the blower 10 by the output from the thermocouple 29. Quantity is supplied. At this time, the cross flow fan 17 of the convection blower 18 also rotates in accordance with the amount of combustion through the central operation unit 33 by the output from the thermocouple 29, so that the outside air enters the inside from the grill 3 and warm air. Air flow exiting from the all-broadcasting exit 5 to the outside via the furnace 6b is generated. In this airflow, the heat generated on the burner plate 7 passes the warm air from the all-airway exit 5 to the room via the hot air passage 6b.

Therefore, when the room temperature rises above the predetermined temperature by use, the room temperature detection unit Rt points this increase and sends a detection signal to the central computing device 33. The central computing device 33 selects the forward rotation energization circuit 36 through the geared motor forward and reverse rotation selection circuit 35 to rotate the geared motor 22 forward. Then, the first link 24 rotates at an angle of about 60 degrees from the position of the solid line in FIG. 2 to the position of the dashed line in the direction of the arrow A. Accordingly, the second link 25 and the third link 26 are connected. Rotate in the directions of arrows B and C, respectively, to position the dashed-dotted line. As a result, the damper 21 rotates in the direction of the arrow C together with the rotation shaft 20, the pin portion 21a is separated from the rear end a so as to elastically contact the front end b of the warm air passage 6b, Opening / closing conversion is performed in which the outlet 4 is opened and the all-broadcast outlet 5 is closed. At this time, since the magnet 27 is opposed to the guide switch 28 as the second link 25 is displaced from the solid line to the position of the one-dot chain line, the switch 28 is connected and sent out by the conversion end detecting unit 37. Detect that the sphere has been converted. By the detection of the conversion end detection unit 37, the central computing device 33 increases the amount of current supplied to the motor 19 through the rotation speed control circuit 39, thereby increasing the rotation speed of the cross flow fan 17 and convection. The air volume from the blower 18 is increased more than the air volume from the all-broadcast outlet 5. As a result, the airflow of the large air volume from the upstream broadcast outlet 4 is generated and convection the indoor air in the vertical direction.

That is, specifically, the combustion amount of the burner is set to 900 Kcal / h to 3000 Kcal / h, and the air volume is reduced to 500 rpm to 700 rpm. When the broadcast is released, the burner burn rate is set to 900Kcal / h to 3000Kcal / h, and the air volume is proportionally adjusted to 800 rpm. As a result, the combustion amount of the burner is also varied by the room temperature detector. This convection makes the temperature distribution in the room uniform. On the other hand, when the room temperature detection unit Rt detects that the room temperature is lower than the set temperature, a signal is sent to the central operation unit 33, and the central operation unit 33 rotates the detection signal from the thermocouple output detection unit 32. The power supply to the motor 19 of the convection blower 18 is lowered to fit the driving state of the combustion blower 10 (500 rpm to 700 rpm), and is sent to the male control circuit 39 and the convection blower ( It operates to lower the rotation speed of 18). The rotation speed control detection circuit 42 detects the decrease in the energization amount of the motor 19 by the rotation speed control circuit 39 and sends a signal to the central computing device 33. Then, the geared motor forward and reverse rotation selection circuit 35 reversely rotates the geared motor 22 through the reverse rotation energizing circuit 41 after the rotation speed control detection circuit 42 is detected. With the reverse rotation of the geared motor 22, the first link 24 is rotated in the opposite direction to the arrow A in FIG. 2 to return to the original line position from the position of the dashed line, and the second and third links ( 25 and 26 are also rotated in the opposite direction to the arrow (B, C) to return to the original line position from the position of the dashed line. At the same time, the damper 22 reversely rotates at an angle of about 20 degrees with the rotation shaft 20 at the position of one-dot chain line, and separates the fin portion 21a from the front end b of the warm air passage 6b like a solid line. Elastic contact with a). Thus, the upper broadcast outlet 4 is closed by the damper 21, the all-broadcast outlet 5 is opened, the change of the direction of sending the warm air is performed, and the warm air is supplied from the all-broadcast outlet 5 to the stream.

At this time, the magnet 27 of the second link 25 is separated from the guide switch 28, is separated from the propagation range of the magnetic force, opens the guide switch 28, and this conversion is detected by the conversion end detecting unit 37. . As a result, the energization of the geared motor 22 is interrupted, and the geared motor 22 stops.

According to such a structure, the conversion is performed from the all-broadcast outlet 5 to the up-air broadcasting outlet 4, and the convection of the indoor air can be promoted, which facilitates the uniformity of the temperature distribution. In this case, opening / closing conversion of all broadcasting exits and upper broadcasting exits is performed, and when the air volume of the upper broadcasting output is larger than the air volume of all broadcasting outputs, if the upper broadcasting output is a large amount of air in the state of all broadcasting outputs, The air volume is discharged, imparts discomfort, and depending on the ventilation structure, there is a fear of causing noise.

On the contrary, in the above configuration, the switching speed of the convection blower 18 is increased by delaying the closing of the all-broadcast outlet 5 by the damper 21 when converting from the all-broadcast outlet 5 to the up-broadcast outlet 4. In other words, since the rotation speed of the convection blower 18 is increased after the closing of the all-broadcast outlet 5, the amount of air blown out from the all-broadcast outlet 5 is discharged to the room, thereby eliminating discomfort. At the same time, in the ventilation structure having a straight line direction from the convection blower 18 to the phase broadcasting outlet 4 as in the present embodiment, the generation of noise can be reduced.

On the contrary, when converting from the upper broadcasting outlet 4 to the all broadcasting outlet 5, the number of revolutions of the convection blower 18 is adjusted to the driving state of the combustion blower 10 and then all broadcasted by the damper 21. Since the outlet 5 is opened, the large air volume for the up-air broadcasting from the all-broadcast outlet 5 is not discharged to the room as in the case described above, and the discomfort can be eliminated and the noise is eliminated.

Next, Figs. 6 to 9 show other embodiments of the present invention, respectively. In FIG. 6, a high rotational speed is realized by using a turbo fan or a silico fan in the fan 13 of the combustion blower 10 of FIG. 2, and a large-scale cross flow fan 17 is provided in the convection blower 18. It can be applied to increase the air flow rate and at the same time have a simple structure.

In FIGS. 7 to 9, two upstream and downstream crossflow fans 60 and 61 are provided in place of the large crossflow fan 17 of FIG. 6, and the crossflow fan 60 at the upper end is used only for convection. In addition, the lower side of the crossflow fan 61 is applied to the role of guiding the warm air to the all-broadcasting outlet 5 while performing auxiliary suction of the primary air for combustion.

In the case of these embodiments of FIGS. 6 to 9, only the different parts have been described with the same reference numerals to the same members as the embodiments of FIGS.

Instead of the damper 21 of the above embodiment, the damper 70 may be configured with a flat portion 70a and a projection 70b formed at the lower end of the flat portion 70a as shown in FIG. In this case, when the damper 70 is in the position of the solid line which closed the image broadcasting exit 4, the projection part 70b acts as a stabilizer, and when the damper 70 is in the position of a dashed line, the flat part 70a is rear Functions as a guider. In the above embodiment, when the conversion from the all-broadcast exit 5 to the upstream broadcast exit 4 is performed by the conversion termination detection unit 37, a delay circuit is provided instead of the conversion termination detection unit 37 to provide 2 to 3 seconds. The signal may be sent to the rotational speed control circuit after a delay.

In the case of the conversion from the upper broadcasting outlet 4 to the all broadcasting outlet 5, the fan is controlled even when the damper 21 is simultaneously converted while controlling the amount of current supplied to the motor 19 of the convection blower 18. Since the damper 21 is converted later than the rotational speed decrease of the damper 21, the large air volume for the upper-broadcast wind is less likely to come out from the upper-broadcast outlet. (21) may be converted, or a delay circuit for delaying the rotational speed control detection circuit by a time of about 2 to 3 seconds may be provided.

And although the convection blower 18 was installed in the hot air path 6b, the blower which has an axial flow fan was installed in the back of the main body case 1, and it blows through the grill 3 by the blower to the hot air blower 6b. You may also do so. In addition, although the room temperature detection part Rt was used as a temperature sensor for conversion of a blower port, you may use manual or a timer instead of room temperature detection part Rt for conversion of a blower outlet, or you may use a timer manually or in addition to using a temperature sensor. You may also do it.

And the guide switch 28 which detects the change of the damper 21 may reverse the switching state of the opening and closing of the said embodiment, and replaces the guide switch 28 with a micro switch, a limit switch, a position sensor, etc. May be installed at the position of the commercial broadcast exit and the position of the all broadcast exit, respectively. In the present invention, the permanent magnet is installed at each of the front end (b) and the rear end (a) of FIG. 2, and the damper 21 is rotated until just before contacting the front end (b) and the rear end (a). After that, the damper 21 may be brought into contact with the front end b and the rear end a by the magnetic force of the permanent magnet. In this way, the damper 21 is not moved until the front end b and the rear end a come into contact with each other, and the geared motor 22 can be stopped immediately before the damper 21. Therefore, the geared motor has a simple structure. The overload of (22) is prevented.

In addition, in the above embodiment, the present invention is applied to a gas hot air heating device, but may be applied to a forced hot air heating device (so-called FF heating device), and an electric heater, petroleum, or kerosene may be used in addition to the fuel gas. In addition, the upper broadcasting outlet 4 is configured to ignite a heat source to discharge warm air, but the upper broadcasting outlet 4 may be blown only in a non-ignition state.

In addition, the rotation angle interval of the damper 21 is not limited only to 60 degrees, and may be appropriately changed according to the implementation state, and specific changes can be made within the scope not departing from the gist of the present invention.

Claims (3)

An all-broadcast exit (5) and an upper-broadcast exit (4) selectively converted by a damper, a blower provided for supplying air to the all-broadcast exit and an upper-broadcast exit, and at least among these all-broadcast exit and the upper-broadcast exit It is provided with a heat source that makes the wind from all broadcast exits the warm air, and when the upper broadcast exit 4 is opened, a larger air volume than the opening of the all broadcast exit 5 is opened through the upper broadcast exit 4. In the warm air heating device to be supplied to the air conditioner, at the time of converting from the all-broadcast outlet (5) to the up-casting outlet (4), the number of revolutions of the blower is increased after the conversion of the damper is completed, and all-broadcasting from the up-casting outlet (4) And a control means for converting the damper after the rotation speed of the blower is lowered when converting to the outlet (5). The method according to claim 1, wherein the number of revolutions of the convection blower is increased by delaying the damper by the time of about 2 to 3 seconds after the start of conversion of the damper from the all-broadcast outlet 5 to the on-air broadcasting outlet 4, When converting from the upper broadcasting outlet 4 to the all broadcasting outlet 5, the damper is changed by delaying a time of about 2 to 3 seconds after starting the adjustment at the rotational speed according to the setting state of the temperature adjusting means. Hot air heating, characterized in that configured. The method according to claim 1, wherein the number of revolutions of the convection blower is increased after detecting the end of the damper conversion from the all-broadcast outlet (5) to the upstream broadcast outlet (4). Hot air heating device characterized in that when the conversion to the all-broadcasting outlet (5) is configured to convert the damper after detecting the end of the adjustment by the number of revolutions according to the set state of the temperature control means.

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