KR940004179B1 - Warm air flow discharging device - Google Patents

Abstract

When the room temp. rises up to a predetermined valve or more, this rise is detected by a room temp. detecting part. The room temp. detecting part sends a detection signal to control means to normally rotate a geared motor. The damper rotates together with a rotary shaft, and an upper discharge port is opened and a front discharge port is closed. Upon this occasion with the displacement of a second link, a magnet confronts a reed switch. When the switch is closed and it is detected that the change over of discharge port is performed, the geared motor is stopped. On the other hand, by this detection, the quantity of power supply to a convection type motor is increased and the rotational speed of a lateral flow fan is increased to increase the air flow rate from a convection type blower more than the air flow rate from the frontward discharge port. An air current of a large air flow rate is generated from the upward discharge port to allow indoor air to counter flow vertically.

Description

Hot Air Discharge Device

1 to 4 show a first embodiment of the present invention,

1 and 2 are longitudinal cross-sectional views viewed from different directions.

3 is a broken front view of a gas hot air heater.

4 is an enlarged perspective view of the main portion.

5 is a longitudinal sectional view showing a second embodiment of the present invention.

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

* Explanation of symbols for main parts of the drawings

1: main body case 4: upward discharge outlet

5: Front discharge outlet 6b: Warm wind path

7: burner plate (heat source) 10: blower for combustion

18: convection blower 21: damper (selective switching means)

31 temperature control means 50 cross flow fan (selective switching means)

54: guideway (selective switching means) R _f : temperature sensor (room temperature detection unit)

The present invention relates to a hot air discharge device that is improved to provide a front discharge port and an upper discharge port and to selectively open and close these discharge ports.

In a hot air heater, which is one example of a conventional hot air discharge device, a discharge port is formed on the front surface of the main body case, and the heat from the heat source is forced by the blower into the room from the discharge port as hot air. Because of this, since the warm air heater is installed in the lower part of the room such as the floor, the warm air is discharged to the lower part of the room and the temperature distribution of the room is relatively good. However, since the warmer is light and moves upwards, the warm air heater stays in the upper part of the room. Done.

In order to solve such a conventional problem, an upper discharge outlet for discharging warm air is provided in addition to a discharge outlet (in the present invention, a front discharge outlet). It has been desired to have a hot water discharge device in which warm water is not stirred and only warm water remains in the upper part of the room.

The present invention has been made in consideration of such a situation, and an object thereof is to selectively open and close the front discharge outlet and the upper discharge outlet as desired, and to facilitate the convection of indoor air during the switching to the upper discharge outlet. It is to provide a warm air discharge device which can prevent the residence in the upper part of the room and further promote the uniformity of the temperature distribution.

The present invention provides a front discharge port and an upper discharge port, selective switching means for selectively switching the front discharge port and the upper discharge port, and installed to supply wind by the front discharge port and the upper discharge port, and the wind from at least the front discharge port among these discharge ports is discharged. It has the structure provided with the heat source and blower for making warm air.

Further, when the upper discharge port is opened, control means for discharging a larger air volume from the upper discharge port to the outside than when the front discharge port is opened is provided.

In addition, the selection switching means is adapted to be operated arbitrarily by manual.

In addition, the selection switching means is adapted to be operated by a timer.

In addition, the selection switching means is configured to operate by sensing the temperature state by a temperature sensor.

In addition, the selection switching means is operated at the same time by manual operation, at the same time detect the room temperature by the temperature sensor.

In addition, the selection switching means is operated by a timer and at the same time detects a room temperature state by a temperature sensor.

In addition, the selection switching means is to operate by sensing the room temperature state by the temperature sensor and at the same time by the upper air discharge through the hot air passage to open the upper discharge port at the time of opening from the front discharge port by the manual discharge. Control means for discharging from the outside to the outside.

According to the present invention configured as described above, by switching the front discharge port and the upper discharge port, convection of indoor air can be promoted, and the warm air is not retained in the upper portion, and the temperature distribution is further promoted.

In addition, when the upper discharge port is opened by the control means, a larger air volume is discharged from the upper discharge port to the outside via the hot air path than the opening from the front discharge port.

Further, the selection switching means may be operated by manual, timer or temperature sensor.

In addition, the selective switching means is operated as desired by manual and at the same time detects the room temperature state by the temperature sensor.

In addition, the selective switching means detects a room temperature state by a temperature sensor and operates the upper discharge outlet to discharge a larger air volume from the upper discharge outlet through the hot air path than the opening of the front discharge outlet. It is.

Next, a first embodiment in which the present invention is applied to a gas warm air heater will be described with reference to FIGS. 1 to 4.

First, in Figs. 1 to 3, 1 is a main box case of a flat box shape, and an duct 2 of an open top type is disposed inside. 3 is an intake grille formed on the rear surface of the main body case 1, 4 and 5 are the upper discharge port and the front discharge port formed adjacent to each other on the upper surface and upper front of the main body case 1, 6b is these grills (3) , The upper discharge port 4 and the front discharge port 5 is a hot air path for communicating with each other. 6 is a box provided 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 source. 8 is a guide wall provided to surround the ceramic burner plate 7, and 9 is provided between the guide wall 8 and the duct 2, and the hole 9a for secondary air inflow is formed in the outer surface. Guide duct. 10 is a combustion blower, which consists of a scroll casing 11 and a fan 13 driven by a motor 12. In the combustion blower 10, the scroll casing 11 communicates a bell mouse portion (not shown) to the outside air, and connects a discharge port (not shown) to 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 pipe 15, and the other end is led to the fuel gas source (not shown) via the supply pipe 16. As shown in FIG.

In addition, 17 is a crossflow fan of the convection blower 18, which is arranged in a horizontal state in the hot air blower 6b and is driven by the motor 19. 20 is a horizontal pivot of the switching mechanism, which is rotatably supported at the corners of the upper discharge port 4 and the front discharge port 5 in the main body case 1.

21 is a damper formed by an elastic member such as a metal, which is thin and possible to have a long rectangular shape. This is a temperature sensor that selects the upper discharge port 4 and the front discharge port 5 according to the room temperature by the room temperature detection unit R _f . 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 located 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 through the speed reduction mechanism. One end of the first link 24 is fixed to the output shaft 23, and one end of the second link 25 is rotatably supported at the other end of the first link 24. The second link 25 is formed of a leaf spring having a central portion in a corrugated shape, and elastically stretchable by a predetermined amount in the longitudinal direction. At the same time, the damper 21 is elastically contacted with the discharge port to secure the sealed state. 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. A magnet 27 is fixed to the second link 25 as shown in FIG. 4, and the magnet 27 is connected to the lead switch 28 in a state where the front discharge port 5 is closed by the damper 21. It is facing. At the time of forward discharge, the damper 21 moves the fin portion 21a to the hot air passage 6b, as shown by the solid line in FIG. 2 and FIG. 6 (the solid line position and the dashed-dotted line position are reversed in FIG. 4). The upper discharge port 4 is closed by being separated from the front end b and elastically contacting the rear end a, and the front discharge port 5 is opened. Further, on the burner plate 7, the flame detection thermocouple 29 and the ignition spark electrode 30 are arranged in opposing states.

Next, the operation of the above configuration will be described.

First, when the combustion blower 10 is driven by operating the temperature adjusting means 31 while the power switch (not shown) is turned on, the fan 13 is rotated so that the outside air from the scroll casing 11 is mixed with the mixing chamber. At the same time as being supplied into 6a, fuel gas is injected into the mixing chamber 6a from the fuel gas source through the supply pipe 16, the nozzle 14, and the guide pipe 15 in sequence. As a result, a mixed gas is generated in the mixing chamber 6a, and a flame ignited by the spark electrode 30 is generated when the burner plate 7 passes upward from below. On the other hand, the cross flow fan 17 of the convection blower 18 rotates according to the setting state of the temperature control means 31, whereby the outside air is blown in from the grill 3 to the inside, and the hot air passage 6b is opened. Air flow exiting from the front discharge port 5 to the outside is produced | generated. The heat generated on the burner plate 7 by piggybacking the air flow becomes hot air from the front discharge port 5 via the hot air passage 6b and is discharged into the room. On the other hand, on the burner plate 7, the thermocouple 29 is output according to the combustion state, and the output is detected by the thermocouple output detection unit (not shown), and the combustion blower 10 is controlled by the control means (not shown). The rotational speed is controlled by adjusting the electric current supply amount with respect to the motor 12 of ().

When the room temperature rises above a predetermined value with use, the room temperature detection unit R _t detects the rise, and sends a detection signal to the control means to rotate the gear motor 22 forward. Then, the first link 24 is rotated at an angle of approximately 60 degrees from the position of the solid line in FIG. 2 to the one-dashed line position in the direction of the arrow A, whereby the second link 25 and the third link 26 are respectively arrows. It rotates to (B), (C) direction, and becomes a dashed-line position. As a result, the damper 21 rotates along the rotation shaft 20 in the direction of the arrow C, and 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, whereby the upper discharge port is discharged. (4) is opened and the front discharge port 5 is closed to open and close switching.

At this time, since the magnet 27 faces the lead switch 28 as the second link 25 is displaced from the solid line to the one-dot chain position, the switch 28 is turned off to detect that the discharge port is switched. . By this detection, the energization to the gear motor 22 is cut off and the gear motor 22 is stopped.

On the other hand, the detection increases the amount of current supplied to the motor 19 for convection to increase the number of revolutions of the cross flow fan 17, so that the amount of air from the convection blower 18 is higher than the amount of air from the front discharge port 5. Increase. As a result, as shown by the white arrows in FIG. 2, a large amount of air flow from the upper discharge port 4 is generated to convection the indoor air in the vertical direction.

Specifically, the combustion amount of the burner is set to 900 Kcal / h to 3000 Kcal / h, and the air volume is set to 500 rpm to 700 rpm in proportion to this. At the time of upward discharge, the burner burn rate was 900 Kcal / h to 3000 Kcal / h, and the air flow was 800 rpm in proportion to this. As a result, the burned amount of the burner was also varied by the room temperature detector.

By this convection, the warmth staying in the upper part of the room is agitated and the temperature distribution in the room is made uniform. On the other hand, when the room temperature detection unit R _t detects that the room temperature is lower than the set temperature, a signal is sent to the control means, so that the amount of current supplied to the motor 19 of the convection blower 18 is driven by the combustion blower 10. It lowers to what is suitable for a state (500rpm-700rpm as mentioned above), and acts to lower the rotation speed of the convection blower 18. As shown in FIG.

Thereafter, the gear motor 22 is rotated in reverse.

As the gear motor 22 rotates in reverse, the first link 24 rotates in a reverse direction to the arrow A in FIG. 2 to return to the original solid line position from the position of the dashed line, and the second and third links ( 25) and 26 also rotate in the opposite direction to the arrows B and C to return from the dashed-dotted line position to the original solid line position. At the same time, the damper 21 reversely rotates at an angle of about 60 degrees with the rotation shaft 20 from the one-dot chain position to separate the fin portion 21a from the front end b of the hot air passage 6b like a solid line, and thus the rear end a ) Elastic contact. The upper discharge port 4 is closed by the damper 21, the front discharge port 5 is opened to switch the discharge direction of the warm air, and the warm air is supplied from the front discharge port 5 to the room. At this time, the magnet 27 of the second link 25 is separated from the lead switch 28 to be out of the magnetic force range with respect to the lead switch 28, and the lead switch 28 is opened, and this switching is performed by a switching detection unit (not shown). Is detected by). At this time, the gear motor 22 is stopped by stopping the energization of the gear motor 22.

According to the above configuration, switching from the front discharge port 5 to the upper discharge port 4 is performed, and at this time, convection of air is promoted to agitate the warmth of the room, further promoting the uniformity of the temperature distribution.

Next, Fig. 5 shows a second embodiment of the present invention.

In the second embodiment, instead of the damper 21 and the switching mechanism of the first embodiment, a crossflow fan 50 for upward discharge is newly installed. This crossflow fan 50 is accommodated in the box-shaped casing 51 and is located in the part of the upper discharge port 4 of 1st Example. The casing 51 is provided with a suction port 52 adjacent to the front discharge port 5, and an upper discharge port 53 is provided on the upper surface thereof, and these suction ports 52 and the upper discharge port 53 are guide paths 54. It is communicated by.

Thus, the transverse flow fan 50 is kept stationary at the time of forward discharge, and is supplied from the front discharge port 5 to the room as indicated by the thick arrow in FIG. As the room temperature rises, the cross flow fan 50 is rotated in the above state. As a result, as shown by a thin arrow in the figure, the warm air and the air from the front discharge port 5 are sucked from the suction port 52 and discharged into the room from the upper discharge port 53 through the guide path 54. Generate convection. In this case, the cross flow fan 17 can also serve as a combustion air fan of the burner.

In this case, when the cross flow fan 50 is driven, the rotation speed of the cross flow fan 17 may be lowered to reduce the amount of hot air discharge from the front discharge port 5, or the rotation speed of the cross flow fan 50 may be reduced. It may raise and make it larger than the rotation speed of the cross flow fan 17. FIG.

Instead of the damper 21 in the first embodiment, the damper 50 is formed in the flat portion 60a and the triangular projection formed at the tip of the flat portion 60a as shown in FIG. You may comprise with (60b). In this case, the projection 60b acts as a stabilizer when the damper 60 is in the solid line position in which the upper discharge port 4 is closed, and the flat portion 60a acts as the rear guider when the damper 60 is in the position of the dashed line. do.

In addition, although the convection blower 18 is provided in the hot air path 6b, even if the blower which has an axial fan is installed in the back surface of a main body case, it blows through the grill 3 by the blower to the warm air path 6b. good.

In the present invention, the permanent magnet is provided at each position of the front end (b) and the rear end (a) of FIG. 2, and the damper 21 is rotated to the front just in contact with the front end (b) and the rear end (a), and thereafter. The damper 21 may contact the front end b and the rear end a in an airtight state by the magnetic force of the permanent magnet. In this way, the damper 21 does not need to be moved until it comes in contact with the front end b and the rear end a, and the gear motor 22 can be stopped immediately before the gear motor 22. Overload) can be prevented.

In addition, the above embodiment was applied to a gas hot air heating device as a hot air discharge device, but may be applied to a hot air discharge device or a forced exhaust type heating device (so-called FF type heating device) of clothing or fabric dryer, and as a heat source not only fuel gas You can also use electric heaters, oil or kerosene.

In addition, although the upper discharge and the forward discharge are switched by the temperature sensor, the user may perform the operation manually arbitrarily, or when the temperature is set by the temperature sensor, the switching is performed by using an electronically controlled priority circuit. May be operated manually.

In addition, the switching of the upward discharge and the forward discharge may be performed when the set temperature is reached by the temperature sensor, so that the timer can be preferentially performed by the timer. In particular, when the present hot air discharge device is used for a heater, it is possible to eliminate unpleasant feelings that may be received by the front air outlet from some people.

This effect is particularly remarkable in switching the upward and forward discharge by manual operation. In the above embodiment, the heat source is ignited from the upper discharge port 4 to produce warm air. However, the upper discharge port 4 may be blown only with no heat source.

In addition, the switch of the discharge port is considered to be a combination of three types of temperature sensor and manual, temperature sensor and timer, or timer and manual, but the order of priority of the combination may be preceded by either.

At the time of switching detection of the damper 21, not only the lead switch 28 but also a limit switch or a micro switch or a position sensor may be provided at the upper discharge position and the front discharge position, respectively.

Further, the distance between the rotation angles of the dampers 21 is not limited to 60 degrees, and various modifications can be made within the scope of the present invention without departing from the gist of the present invention.

Claims (8)

At least one of the discharge outlets and the selective switching means for selectively switching the front discharge outlets 5 and the upper discharge outlets, and for supplying air from these front discharge outlets 5 and the upper discharge outlets; A warm air discharge device comprising a heat source (7) and a blower for making the wind from the front discharge port warm air. 2. The warm air discharge device according to claim 1, further comprising a control means for discharging the air volume greater than that from the front discharge port when the upper discharge port is opened to the outside from the upper discharge port. The hot air discharging device according to claim 1, wherein the selection switching means is arbitrarily operated by manual operation. The warm air discharge device according to claim 1, wherein the selection switching means is operated by a timer. The hot air discharge device according to claim 1, wherein the selective switching means is operated by sensing a room temperature state by a temperature sensor. The hot air discharge device according to claim 1, wherein the selective switching means is operated by a manual operation and at the same time detects a room temperature state by a temperature sensor. The hot air discharge device according to claim 1, wherein the selective switching means is operated by a timer and senses and operates a room temperature state by a temperature sensor. The hot air blower according to claim 1, wherein the selective switching means is operated by sensing a room temperature state by a temperature sensor and at the same time by manual opening of the upper discharge port, the air blower having a greater air volume than opening from the front discharge port. And a control means for discharging to the outside from the upper discharge port through the hot air discharge device.

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