JP7397370B2 - floor-standing heating device - Google Patents

Description

The present disclosure relates to a floor-standing heating device.

The radiant heater disclosed in Patent Document 1 includes a planar heater provided with a heating element, an air path provided on the back side of the planar heater, and an air blower disposed in the air path. The air passage communicates the inlet and the outlet, and the air sucked in from the inlet is heated by the planar heater and then blown out from the outlet into the room as warm air.

Japanese Patent Application Publication No. 2006-10156

In a heating device that blows out hot air as disclosed in Patent Document 1, a fan serving as an air blower is arranged relatively close to a heater. Therefore, the thermal load on the fan increases due to the effect of radiant heat from the heater, and there is a risk that the fan may malfunction.

An object of the present disclosure is to provide a floor-standing heating device that suppresses thermal load on a fan due to radiant heat from a heater.

A first aspect of the present disclosure includes:
a casing (11) in which an internal space (I) is formed;
a first heater (31) disposed in the internal space (I) and providing radiant heat;
a reflecting plate (40) disposed in the internal space (I) and reflecting heat rays generated from the first heater (31) toward the front surface (12) of the casing (11);
a suction port (20) formed in the casing (11) and sucking air from the target space (S);
an air outlet (21) formed in the casing (11) and blowing air into the target space (S);
an air passage (P) provided in the internal space (I) and communicating with the suction port (20) and the blowout port (21);
a fan (50) disposed in the air passageway (P) that conveys air from the suction port (20) toward the blowout port (21);
The air passage (P) is formed so that air heated by the first heater (31) flows toward the fan (50),
The reflector (40) is a floor-standing heating device arranged so as to cross the shortest path connecting the first heater (31) and the fan (50).

In the first aspect, the reflector (40) is arranged so as to cross the shortest path connecting the first heater (31) and the fan (50), so that the heat rays from the first heater (31) are transmitted to the fan (50). 50) can be suppressed from being directly irradiated. In addition, air flowing near the first heater (31) can be prevented from reaching the fan (50) through the shortest distance. As a result, the floor-standing heating device (10) can suppress the heat load on the fan (50), and can suppress problems occurring in the fan (50).

A second aspect of the present disclosure includes, in the first aspect,
comprising a panel (60) that transmits heat rays from the first heater (31);
The panel (60) is arranged in front of the heater,
The shortest distance between the first heater (31) and the fan (50) is longer than the shortest distance between the first heater (31) and the panel (60).

In the second aspect, the first heater (31) and the fan (50) are located relatively apart from each other, so that the influence of radiant heat from the first heater (31) on the fan (50) can be suppressed. .

A third aspect of the present disclosure provides, in the first or second aspect,
The fan (50) is arranged below the first heater (31).

In the third aspect, since the thermal influence of the first heater (31) is concentrated in the upper part of the internal space (I), by locating the fan (50) below, the thermal influence on the fan (50) can be reduced. .

A fourth aspect of the present disclosure includes, in the first or second aspect,
The fan (50) is arranged above the first heater (31) in the air passage (P).

Also in the fourth aspect, the thermal load on the fan (50) can be suppressed, and malfunctions occurring in the fan (50) can be suppressed.

A fifth aspect of the present disclosure includes, in the fourth aspect,
further comprising a second heater (33) that heats the air in the air passage (P),
The second heater (33) is arranged below the first heater (31).

In the fifth aspect, since the fan (50) and the second heater (33) are provided at a relatively distant position, it is possible to suppress the influence of heat load caused by the second heater (33) on the fan (50). .

A sixth aspect of the present disclosure provides, in any one of the first to fifth aspects,
The reflective plate (40) is
A first sloped portion (R1) is provided that slopes downward toward the front surface (12) so that the reflected heat rays travel upward toward the front surface (12).

In the sixth aspect, by making the traveling direction of the reflected heat rays upward, radiant heat can be applied to a height that hits not only the feet of the person in front of the front but also the person's torso.

A seventh aspect of the present disclosure provides, in any one of the first to sixth aspects,
The reflective plate (40) is
A second sloped portion (R2) is provided that slopes upward toward the front surface (12) so that the reflected heat rays travel downward toward the front surface (12).

In the seventh aspect, for example, by directing the reflected heat rays in a downward direction, radiant heat can be applied to a height that hits a person's torso.

An eighth aspect of the present disclosure provides, in any one of the first to seventh aspects,
The air passage (P) is between the reflective plate (40), which is disposed between the first heater (31) and the rear surface (13) of the casing (11), and the rear surface (13). including a first space (25) formed;
The fan (50) is arranged below the first heater (31),
The reflector (40) has a guide portion (42) that directly guides air flowing from above to below in the first space (25) to the fan (50),
The guide portion (42) is formed to bulge toward the rear surface (13) side relative to the fan (50).

In the eighth aspect, the air flowing in the first space (25) can flow into the fan (50) along the guide portion (42). This makes it possible to suppress the ventilation resistance of the air passage (P).

FIG. 1 is a schematic perspective view of a floor-standing heating device according to an embodiment. FIG. 2 is a cross-sectional view of the floor-standing heating device perpendicular to the left-right direction. FIG. 3 is a block diagram regarding the control section. FIG. 4 is a sectional view taken along the line IV-IV in FIG. 2. FIG. 5 is a diagram illustrating the direction in which heat rays reflected by a reflector travel. FIG. 6 is a diagram corresponding to FIG. 2 of a floor-standing heating device according to modification 1. FIG. 7 is a diagram corresponding to FIG. 2 of a floor-standing heating device according to a second modification. FIG. 8 is a diagram corresponding to FIG. 2 of a floor-standing heating device according to modification 3. FIG. 9 is a diagram corresponding to FIG. 2 of a floor-standing heating device according to modification 4. FIG. 10 is a diagram corresponding to FIG. 2 of a floor-standing heating device according to modification 5.

Embodiments of the present disclosure will be described in detail below with reference to the drawings. Note that the present disclosure is not limited to the embodiments shown below, and various changes can be made without departing from the technical idea of the present disclosure. Each drawing is for conceptually explaining the present disclosure, so dimensions, ratios, or numbers may be exaggerated or simplified as necessary to facilitate understanding.

(1) Overview of floor-standing heating device A floor-standing heating device (10) according to an embodiment will be described with reference to FIGS. 1 and 2. In the following description, "upper", "lower", "front", "rear", "right", and "left" basically mean the directions indicated by the arrows in FIG. 1. The thick arrows shown in FIGS. 1, 2, and 6 to 9 indicate the direction in which air flows.

The floor-standing heating device (10) heats the indoor space (S), which is the target space. The floor-standing heating device (10) is installed on the floor (F) of the indoor space (S). The floor-standing heating device (10) heats the indoor space (S) using radiant heat. In addition, the floor-standing heating device (10) heats indoor air in the indoor space (S) and supplies the heated air to the indoor space (S).

The floor-standing heating device (10) includes a casing (11), a first heater (31), a reflector (40), a fan (50), and heat-resistant glass (60). The first heater (31) emits far infrared rays (heat rays). The reflector (40) reflects the heat rays emitted from the first heater (31) toward the front of the casing (11). The heat-resistant glass (60) absorbs heat emitted from the first heater (31). The heat-resistant glass (60) transmits the heat rays from the first heater (31). The heat-resistant glass (60) functions as a heat absorbing plate or a protective plate.

(2) Casing The casing (11) is formed into a hollow, substantially rectangular parallelepiped shape. The casing (11) is made of, for example, a resin material. The casing (11) is formed into a vertically elongated box shape. The casing (11) has six sides (12, 13, 14, 15, 16, 17). The six surfaces include a front surface (12), a rear surface (13), an upper surface (14), a lower surface (15), a right surface (16), and a left surface (17). The front surface (12) is located on the front side of the casing (11), the rear surface (13) is located on the rear side of the casing (11), the top surface (14) is located on the top side of the casing (11), and the bottom surface (15) is located on the top side of the casing (11). ) is located on the lower side of the casing (11), the right surface (16) is located on the right side of the casing (11), and the left surface (17) is located on the left side of the casing (11).

As shown in FIGS. 1 and 2, a rectangular front opening (11a) is formed in the front surface (12) of the casing (11). The front opening (11a) is formed from the upper end of the casing (11) to the vicinity of the suction port (20). The front opening (11a) is formed from the right surface (16) to the left surface (17) of the casing (11). A heat-resistant glass (60) is provided in the front opening (11a). The heat-resistant glass (60) is fixed to the casing (11) so as to close the front opening (11a).

An inlet (20) and an outlet (21) are formed on the front surface (12) of the casing (11). The suction port (20) is an opening for sucking air from the indoor space (S). The air outlet (21) is an opening for blowing out the air inside the casing (11) into the indoor space (S). The inlet (20) and the outlet (21) are located at the lower part of the casing (11). Specifically, the air outlet (21) is located at the lower end of the casing (11). The air outlet (21) is located near the floor (F) of the indoor space (S). The air outlet (21) extends left and right from the right surface (16) to the left surface (17) of the casing (11). The suction port (20) is located above the air outlet (21). The air outlet (21) extends left and right along the upper side of the suction port (20). In the internal space (I) of the casing (11), an air passage (P) is formed that communicates the inlet (20) and the outlet (21).

(3) Heater The floor-standing heating device (10) of this embodiment has two first heaters (31). The number of first heaters (31) is merely an example, and may be one, three or more. Each first heater (31) is arranged in the internal space (I) of the casing (11). Specifically, each first heater (31) is arranged in a first flow path (23), which will be described later. Each first heater (31) is fixed to a support member (32) (see FIG. 4) provided in the internal space (I) of the casing (11).

The two first heaters (31) are arranged behind the heat-resistant glass (60). The first heater (31) provides radiant heat. The first heater (31) is coated with far-infrared rays containing ceramic. Each first heater (31) is formed into a pipe shape or a substantially rod shape extending in the left-right direction. The two first heaters (31) are arranged side by side in the vertical direction. In other words, the two first heaters (31) are arranged in the direction along the front surface (12) and rear surface (13) of the casing (11). The two first heaters (31) are arranged parallel to each other at equal intervals. The heat rays emitted from the first heater (31) spread around the entire circumference with the axis of the first heater (31) as the center. In other words, when looking at the casing (11) from left and right, the first heater (31) emits heat rays radially.

(4) Reflection plate The reflection plate (40) is formed of a flat metal plate. The reflector (40) is arranged in the internal space (I). The reflector (40) is arranged between the first heater (31) and the rear surface (13). The reflective plate (40) is arranged facing the front surface (12) and the rear surface (13). The left and right ends of the reflector (40) are fixed to the support member (32) (see FIG. 4). The lower end of the reflector (40) is fixed to the support plate (39). A gap is formed between the upper end of the reflector (40) and the upper surface (14). This gap is a communication path (24) that will be described later.

(5) Fan The fan (50) is arranged in the air passage (P). The fan (50) transports air in the air passageway (P) from the suction port (20) toward the blowout port (21). The fan (50) of this embodiment is a cross-flow type fan. As schematically shown in FIG. 1, the fan (50) includes a fan body (51) extending in the left-right direction and a fan motor (52) that rotationally drives the fan body (51). The fan (50) is arranged below the first heater (31) in the internal space (I) of the casing (11).

Specifically, the fan (50) is arranged downstream of the first heater (31) in the air passage (P). The fan (50) is arranged near the air outlet (21). Specifically, the fan (50) is arranged at approximately the same height as the air outlet (21). The fan (50) is arranged closer to the front (12) than in the middle between the front (12) and the rear (13). The shortest path L1 connecting the fan (50) and the first heater (31) is longer than the shortest path L2 connecting the first heater (31) and the heat-resistant glass (60).

(6) Heat-resistant glass Heat-resistant glass (60) is an example of the panel (60) of the present disclosure. The heat-resistant glass (60) is formed into a flat plate shape. The heat-resistant glass (60) is provided in the front opening (11a) of the casing (11). Heat-resistant glass (60) is formed along the front surface (12) of the casing (11). Specifically, the heat-resistant glass (60) extends vertically from the upper end of the casing (11) to the suction port (20). The heat-resistant glass (60) extends left and right from the left surface (17) to the right surface (16) of the casing (11).

The heat-resistant glass (60) is made of a glass material with excellent heat resistance. The heat-resistant glass (60) has a property of transmitting far-infrared rays emitted from the first heater (31) and the reflector (40). On the other hand, the heat-resistant glass (60) has a property of absorbing heat emitted from the first heater (31) and the reflector (40).

(7) Air passage The air passage (P) is provided in the internal space (I) of the casing (11). The air passage (P) communicates the inlet (20) and the outlet (21). The air passage (P) includes, in order from upstream to downstream of the air flow, a suction space (22), a first passage (23), a communication passage (24), a second passage (25), and a blowout space ( 26).

The suction space (22) is connected to the suction port (20). The suction space (22) is formed on the back side (rear side) of the suction port (20).

The first flow path (23) communicates the suction space (22) with the upstream end of the communication path (24). The first channel (23) is formed between the heat-resistant glass (60) and the reflective plate (40). Strictly speaking, the first flow path (23) is formed between the rear surface of the heat-resistant glass (60) and the front surface of the reflection plate (40). The two first heaters (31) are arranged to face the first flow path (23). The first flow path (23) constitutes a flow path through which air flows upward.

The communication path (24) is formed between the first flow path (23) and the second flow path (25). The communication path (24) is formed above the reflection plate (40). Strictly speaking, the communication path (24) is a space between the upper end of the reflector (40) and the lower surface (15) of the casing (11). In the communication path (24), the upward air flow makes a U-turn and becomes a downward air flow.

The second flow path (25) communicates the downstream end of the communication path (24) and the air outlet (21). The second flow path (25) is formed between the reflection plate (40) and the rear surface (13) of the casing (11). The second flow path (25) is an example of the first space (25) of the present disclosure. The second flow path (25) constitutes a flow path through which air flows from above to below.

The blowout space (26) communicates the downstream end of the second flow path (25) and the blowout port (21). In the blowout space (26), air flows from the rear surface (13) to the front surface (12). A fan (50) is arranged in the blowout space (26). The fan (50) is arranged below the two first heaters (31).

(8) Control unit As shown in FIG. 3, the floor-standing heating device (10) includes a control unit (C). The control unit (C) controls the fan motor (52) and the first heater (31). Specifically, the control unit (C) controls ON/OFF of the fan motor (52) and the rotation speed of the fan motor (52). The control unit (C) controls ON/OFF of the first heater (31) and the output of the first heater (31).

(9) Operation Operation The operation operation of the floor-standing heating device (10) will be described with reference to FIGS. 1 and 2. When the floor-standing heating device (10) is in operation, the first heater (31) is energized and the fan (50) is in operation.

When the first heater (31) is energized, a hot wire is emitted from the first heater (31). A portion of the heat rays emitted from the first heater (31) directly advances forward. The remainder of the heat rays emitted from the first heater (31) are reflected by the reflector (40) and then indirectly proceed forward. The heat rays traveling forward pass through the heat-resistant glass (60). In this way, radiant heat is released to the front side of the casing (11). The heat-resistant glass (60) absorbs the heat of the first heater (31).

When the fan (50) is operated, indoor air in the indoor space (S) is sucked into the suction port (20). This air flows into the first flow path (23) from the suction space (22) and flows upward toward the communication path (24). The air in the first flow path (23) is sequentially heated by the two first heaters (31) and the heat-resistant glass (60) that absorbs heat from the first heaters (31).

The air heated in the first flow path (23) flows into the second flow path (25) via the communication path (24). The air in the second flow path (25) flows downward while being heated by the reflection plate (40) that absorbs heat from the first heater (31).

This air flows into the blowing space (26) after passing the lower end of the reflecting plate (40). After passing through the fan (50), the air in the blowout space (26) is blown out as warm air from the blowout port (21) into the indoor space (S).

In this way, the floor-standing heating device (10) of this embodiment blows out hot air from the air outlet (21), thereby absorbing not only the radiant heat from the heat-resistant glass (60) but also the radiant heat from the air outlet (21). The indoor space (S) can be heated with warm air. The air outlet (21) is located at the bottom of the casing (11). Specifically, the air outlet (21) is located along the floor (F). Therefore, warm air can be blown out to the feet of the user, improving the user's comfort.

(10) Shape of Reflector Plate The shape of the reflector plate (40) of the present disclosure will be described using FIGS. 2, 4, and 5. The arrows shown in FIG. 5 indicate the direction in which the reflected heat rays travel.

The reflecting plate (40) extends in the left-right direction and has substantially the same cross-sectional shape in the left-right direction. The reflective plate (40) has a first curved surface portion (41), a second curved surface portion (42), and a connecting portion (43). The first curved surface section (41) is arranged above the second curved surface section (42). The connecting portion (43) connects the first curved surface portion (41) and the second curved surface portion (42). The first curved surface portion (41) and the second curved surface portion (42) have substantially the same shape.

The first curved surface portion (41) and the second curved surface portion (42) are formed to bulge from the front toward the rear. The shape of the vertical cross section of the first curved surface portion (41) and the second curved surface portion (42) when viewed from the left and right direction is an arc shape. The connecting portion (43) has a flat plate shape extending in the left-right direction. The plate surface of the connecting portion (43) faces the front surface (12) and the rear surface (13). The connecting portion (43) connects to the lower end of the first curved surface portion (41) and the upper end of the second curved surface portion (42).

One first heater (31) is arranged on each curved surface portion (41, 42). The first heater (31) is arranged in front of the bulging top (T) of the curved surface portion (41, 42). The top portion (T) is the rear end of the curved surface portion (41, 42). The first heater (31) is arranged behind the front end of the curved surface portion (41, 42). Specifically, the first heater (31) is placed at the focal point of the parabola of each curved surface portion (41, 42).

(10-1) First sloped portion and second sloped portion Each curved surface portion (41, 42) has a first sloped portion (R1) and a second sloped portion (R2). The first inclined portion (R1) is the lower portion of the curved surface portions (41, 42). The second inclined portion (R2) is the upper portion of the curved surface portions (41, 42). The first slope (R1) slopes downward toward the front surface (12) so that the reflected heat rays are guided upward toward the front surface (12). On the other hand, the second inclined portion (R2) is inclined upward toward the front surface (12) so that the reflected heat rays are guided downward toward the front surface (12).

In this way, each curved surface part (41, 42) of the reflector (40) has the first slope part (R1) and the second slope part (R2), so that the feet of the user who is in front of the front surface (12) are In addition, while radiant heat is directed toward the user's torso, the radiant heat is less likely to hit the user's face. This improves the comfort provided to the user. Specifically, the radiation range of the floor-standing heating device (10) of this embodiment is a height range from a position of 1.8 m forward from the front surface (12) to a height of 1.1 m.

The reflector (40) is arranged to cross the shortest path L1 connecting the first heater (31) and the fan (50). Specifically, the first inclined portion (R1) of the second curved surface portion (42) of the reflector (40) is arranged within the shortest path L1 connecting the first heater (31) and the fan (50). . With this arrangement, the heat rays that go directly from the first heater (31) arranged on the second curved surface part (42) to the fan (50) are directed by the first inclined part (R1) of the second curved surface part (42). be interrupted. Further, due to the arrangement of the second curved surface portion (42), the air heated by the first heater (31) in the first flow path (23) does not directly flow into the fan (50) through the shortest path L1.

(10-2) Guide portion The reflector (40) has a guide portion (42). The second curved surface portion (42) of this embodiment is an example of the guide portion (42). The second curved surface portion (42) directly guides air flowing from above to below in the second flow path (25) to the fan (50). The second curved surface portion (42) is formed to bulge out toward the rear surface (13) than the fan (50). Specifically, the fan (50) is disposed below the lower end of the first inclined portion (R1) of the second curved surface portion (42). Due to this arrangement, the rear end of the second curved surface portion (42) is located further back than the fan (50). By forming the second curved surface portion (42) in this way, the air flowing downward through the second flow path (25) is configured to have a first slope when flowing behind the second curved surface portion (42). It flows toward the fan (50) along the back side of the section (R1).

(11) Features (11-1)
The floor-standing heating device (10) of the present embodiment includes a reflector (40) that reflects heat rays generated from the first heater (31) toward the front surface (12) of the casing (11), and an inlet (20). ) and an air passage (P) communicating with the air outlet (21). The air passage (P) is formed so that air heated by the first heater (31) flows toward the fan (50). The reflector (40) is arranged to cross the shortest path L1 connecting the first heater (31) and the fan (50). Specifically, the first inclined portion (R1) of the second curved surface portion (42) of the reflector (40) is arranged to cross the shortest path L1 connecting the first heater (31) and the fan (50). Ru. Therefore, it is possible to prevent the heat rays emitted from the first heater (31) from directly hitting the fan (50). In addition, the influence of radiant heat on the fan (50) can be suppressed, and the air heated by the first heater (31) can be suppressed from flowing into the fan (50) through the shortest path L1. As a result, the floor-standing heating device (10) can avoid malfunctions of the fan (50) caused by heat load.

(11-2)
In the floor-standing heating device (10) of this embodiment, the shortest distance between the first heater (31) and the fan (50) is shorter than the shortest distance between the first heater (31) and the panel (60). long. As a result, the longer the shortest distance between the first heater (31) and the fan (50), the more the floor-standing heating device (10) suppresses the influence of radiant heat from the first heater (31) on the fan (50). be able to.

(11-3)
In the floor-standing heating device (10) of this embodiment, the fan (50) is arranged below the first heater (31) in the air passageway (P). Since the thermal influence of the first heater (31) is concentrated in the upper part of the internal space (I), by arranging the fan (50) below the first heater (31) in this way, the effect on the fan (50) is The effect of heat can be reduced.

(11-4)
In the floor-standing heating device (10) of the present embodiment, the first inclined portion (R1) of the reflector (40) is configured such that the reflected heat rays advance upward toward the front surface (12) of the casing (11). and slopes downward toward the front (12). In this way, by directing the reflected heat rays upward, radiant heat can be applied not only to the feet of the person in front of the floor-standing heating device (10), but also to a height that hits the person's torso. I can do it. As a result, the floor-standing heating device (10) can improve the comfort felt by people.

(11-5)
In the floor-standing heating device (10) of the present embodiment, the second inclined portion (R2) of the reflector (40) is configured such that the reflected heat rays proceed downward toward the front surface (12) of the casing (11). and slopes upward toward the front (12). In this way, by directing the reflected heat rays in a downward direction, radiant heat can be efficiently applied to a height that hits a person's torso, for example.

(11-6)
In the floor-standing heating device (10) of this embodiment, the air passage (P) is the second flow path (25) (first space) formed between the reflector (40) and the rear surface (13). including. The fan (50) is disposed below the first heater (31) in the second flow path (25), and the reflector (40) is configured to prevent air flowing from above to downward in the second flow path (25). It has a second curved surface portion (42) (guide portion) that directly guides the fan (50). The second curved surface portion (42) (guide portion) is formed to bulge toward the rear surface (13) side relative to the fan (50). With this, the air in the second flow path (25) flowing from above to below passes through the first slope part (R1) of the second curved surface part (42), and the air flows through the first slope part (R1) of the second curved surface part (42). It becomes easier to flow into the fan (50) located below the lower end. As a result, the floor-standing heating device (10) can suppress the ventilation resistance of the air passage (P).

(12) Modifications The above embodiment may have the following modification configuration. Below, the differences from the above embodiment will be mainly described.

(12-1) Modification example 1
In the floor-standing heating device (10) of Modification 1 shown in FIG. 6, the portion corresponding to the front opening (11a) of the casing (11) of the floor-standing heating device of the above embodiment constitutes the suction port (20). do. The suction port (20) of this example is provided with a suction member (60) having a plurality of holes (H). The suction member (60) is an example of the panel (60) of the present disclosure. The suction member (60) is, for example, a punching plate. The punching plate is made of a flat metal material such as SUS. The suction member (60) is provided on the front surface (12) of the casing (11) so as to cover the suction port (20) of the casing (11). The suction member (60) extends in the vertical direction from the upper end to the lower end of the suction port (20). The suction member (60) extends in the left-right direction from the left end to the right end of the suction port (20). The plurality of holes (H) are formed on substantially the entire surface of the suction member (60). Therefore, air from the indoor space (S) can be sucked in from substantially the entire surface of the suction port (20). The panel (60) in this example may be a mesh member.

When the floor-standing heating device (10) is in operation, a part of the heat rays of the first heater (31) advances forward, and the remaining part is reflected by the reflector (40), and finally reaches the casing ( 11) Go forward.

Air in the indoor space (S) is sucked in through substantially the entire surface of the suction member (60). In this way, since the opening area of the suction port (20) of this example can be increased, the suction air volume can be increased. The air passage (P) in this example does not have a suction space (22). Air from the suction port (20) flows directly into the first flow path (23). Air heated by the first heater (31) in the first flow path (23) flows into the second flow path (25) via the communication path (24). The air in the second flow path (25) flows downward while being heated by the reflection plate (40) heated by the first heater (31). After passing through the lower end of the reflector (40), this air flows into the blowout space (26) and passes through the fan (50). The air that has passed through the fan (50) is blown out from the air outlet (21) into the indoor space (S) as warm air.

(12-2) Modification example 2
In the floor-standing heating device (10) of Modification 2 shown in FIG. 7, the floor-standing heating device (10) of Modification 1 is provided with heat-resistant glass (61). The heat-resistant glass (61) is arranged behind the suction member (60) and in front of the first heater (31). Similar to the above embodiment, the heat-resistant glass (61) has the property of transmitting far infrared rays emitted from the first heater (31) and the reflector (40), and the property of transmitting far infrared rays emitted from the first heater (31) and the reflector (40). It has the property of absorbing heat.

The left and right ends of the heat-resistant glass (61) are fixed to support members (not shown) of the casing (11). The lower end of the heat-resistant glass (61) is fixed to the support plate (39). The upper end of the heat-resistant glass (61) is arranged below the upper surface (14). In other words, a gap is formed between the upper end of the heat-resistant glass (61) and the upper surface (14). The heat-resistant glass (61) faces the suction member (60). Specifically, the entire area of the heat-resistant glass (61) is arranged so as to overlap the suction member (60) in the front-rear direction.

The first flow path (23) of Modification 2 is formed between the suction member (60) and the heat-resistant glass (61). Specifically, the first flow path (23) is formed between the front surface of the suction member (60) and the rear surface of the heat-resistant glass (61). A space in which the first heater (31) is arranged is formed between the heat-resistant glass (61) and the reflection plate (40). This space is a space where air does not substantially flow.

When the floor-standing heating device (10) is in operation, a portion of the heat rays of the first heater (31) travels forward, and the remaining portion is reflected by the reflector (40) and travels forward, similar to the above embodiment. Almost all of the heat rays that advance forward pass through the heat-resistant glass (61), head toward the suction member (60), and finally advance toward the front of the casing (11).

Air in the indoor space (S) sucked in through the suction port (20) is heated in the first flow path (23). Specifically, the air in the first flow path (23) is heated by the heat-resistant glass that absorbs heat from the first heater (31). Air in the first flow path (23) flows into the second flow path (25) via the communication path (24). The air in the second flow path (25) flows downward while being heated by the reflection plate (40) that absorbs heat from the first heater (31). The air that has passed through the reflector (40) flows into the blowout space (26) and passes through the fan (50). The air that has passed through the fan (50) is blown out from the air outlet (21) into the indoor space (S) as warm air.

In the floor-standing heating device (10) of this example, the heat absorbed by the heat-resistant glass (61) from the first heater (31) can be used to heat the air in the air passageway (P). In addition, since the heat-resistant glass (61) absorbs heat from the first heater (31), excessive heating of the suction member (60) disposed in front of the heat-resistant glass (61) can be suppressed. As a result, safety for users can be ensured.

(12-3) Modification 3
In the floor-standing heating device (10) of Modification 3 shown in FIG. 8, a front suction member (60) is provided as the panel (60). The front suction member (60) is provided at the suction port (20) similarly to the suction member (60) of Modifications 1 and 2 above. The floor-standing heating device (10) of Modification 3 has a rear suction member (61). The rear suction member (61) is a punching plate having a plurality of holes (H).

The rear suction member (61) is arranged in the first flow path (23). The rear suction member (61) is arranged behind the front suction member (60) and in front of the first heater (31). The left and right ends of the rear suction member (61) are fixed to support members (not shown) of the casing (11). The lower end of the rear suction member (61) is fixed to the support plate (39). The upper end of the rear suction member (61) is fixed to the upper surface (14). The rear suction member (61) faces the front suction member (60). The rear suction member (61) is arranged so as to overlap the entire area of the front suction member (60) in the front-rear direction.

When the floor-standing heating device (10) is in operation, a portion of the heat rays of the first heater (31) travels forward, and the remaining portion is reflected by the reflector (40) and travels forward, similar to the above embodiment. Almost all of the hot wires that advance forward head toward the front suction member (60) via the rear suction member (61), and finally advance toward the front of the casing (11). The rear suction member (61) absorbs part of the heat of the first heater (31).

In the first flow path (23), a portion of the air sucked into the first flow path (23) via the front suction member (60) passes through the plurality of holes (H) of the rear suction member (61). pass. The air in the first flow path (23) is heated by the first heater (31) and the rear suction member (61) that absorbs the heat of the first heater (31). This air flows into the second flow path (25) via the communication path (24). The air in the second flow path (25) flows downward while being heated by the reflection plate (40) that absorbs heat from the first heater (31). The air that has passed through the lower end of the reflector (40) passes through the fan (50) at the bottom of the blowout space (26) and is blown out from the blowout port (21) into the indoor space (S).

Also in this example, the front suction member (60) can be prevented from being excessively heated by the rear suction member (61) absorbing the heat of the first heater (31).

(12-4) Modification example 4
A floor-standing heating device (10) of Modification 4 shown in FIG. 9 is provided with a rear heat-resistant glass (61) in the floor-standing heating device (10) of the above embodiment.

The floor-standing heating device (10) of Modification 4 is provided with a front heat-resistant glass (60) as a panel (60). The front heat-resistant glass (60) is the heat-resistant glass (60) of the above embodiment. Specifically, the front heat-resistant glass (60) is provided in the front opening (11a) of the casing (11). The front heat-resistant glass (60) is formed along the front surface (12) of the casing (11). Specifically, the front heat-resistant glass (60) extends vertically from the upper end of the casing (11) to the suction port (20). The front heat-resistant glass (60) extends left and right from the left surface (17) to the right surface (16) of the casing (11).

Like the front heat-resistant glass (60), the rear heat-resistant glass (61) is made of a glass material with excellent heat resistance and is formed into a flat plate shape. The rear heat-resistant glass (61) has a property of transmitting far infrared rays emitted from the first heater (31) and the reflector (40). The rear heat-resistant glass (61) has a property of absorbing heat emitted from the first heater (31) and the reflector (40).

The rear heat-resistant glass (61) is arranged behind the front surface (12) of the casing (11) and in front of the first heater (31). The rear heat-resistant glass (61) is fixed to the casing (11) in parallel with the front heat-resistant glass (60) via a support member (not shown). The rear heat-resistant glass (61) faces the front heat-resistant glass (60). The height position of the lower end of the rear heat-resistant glass (61) is approximately equal to the height position of the lower end of the front heat-resistant glass (60). The height position of the upper end of the rear heat-resistant glass (61) is lower than the height position of the upper end of the rear heat-resistant glass (61). The entire area of the rear heat-resistant glass (61) overlaps with the front heat-resistant glass (60) in the front-rear direction.

The reflector (40) of Modification 4 includes a front reflector (40a) and a rear reflector (40b). The front reflecting plate (40a) has the same configuration as the reflecting plate (40) of the above embodiment. Also in the fourth modification, the reflection plate (40) is arranged to cross the shortest path L1 connecting the first heater (31) and the fan (50). Specifically, the first inclined portion (R1) of the second curved surface portion (42) of the front reflector (40a) is located on the shortest path L1 connecting the first heater (31) and the fan (50).

The rear reflector (40b) is arranged behind the first heater (31) and the front reflector (40a). The upper end of the rear reflector (40b) is fixed to the casing (11) via the first support plate (35). The lower end of the rear reflector (40b) is fixed to the casing (11) via the second support plate (36).

The rear reflector (40b) includes a third curved surface portion (44) having a substantially arc shape in a cross-sectional view perpendicular to the plane of the paper (left-right direction) in FIG. The third curved surface portion (44) extends in the left-right direction and has substantially the same cross-sectional shape in the left-right direction. Specifically, the third curved surface portion (44) is formed in a curved shape that bulges rearward. A third inclined portion (R3) that reflects the heat rays of the first heater (31) forward is formed on the front surface of the third curved surface portion (44). The rear reflector (40b) prevents air from flowing into the space between the reflector (40) and the rear surface (13).

The first flow path (23) of Modification 4 is formed between the rear heat-resistant glass (61) and the front heat-resistant glass (60). The first flow path (23) constitutes a flow path through which air flows upward. The communication path (24) of Modification 4 is formed between the front heat-resistant glass (60) and the top surface (14). In the communication path (24), the upward air flow makes a U-turn and becomes a downward air flow. The second flow path (25) of Modification 4 is formed between the front reflective plate (40a) and the rear heat-resistant glass (61). The second flow path (25) constitutes a flow path through which air flows downward. The blowout space (26) of Modification 4 is formed on the back side (rear side) of the blowout port (21). A fan (50) is arranged in the blowout space (26).

Similar to the above embodiment, when the first heater (31) is energized, a hot wire is emitted from the first heater (31). A portion of the heat rays emitted from the first heater (31) directly moves forward. The remainder of the heat rays emitted from the first heater (31) indirectly moves forward after being reflected by the front reflector (40a) and the rear reflector (40b). As a result, radiant heat is released to the front side of the casing (11).

When the heat emitted from the first heater (31) passes through the rear heat-resistant glass (61), this heat is absorbed by the rear heat-resistant glass (61). Next, when the heat that has passed through the rear heat-resistant glass (61) passes through the front heat-resistant glass (60), this heat is absorbed by the front heat-resistant glass (60). In this way, by providing the rear heat-resistant glass (61) and the front heat-resistant glass (60) on the front side of the first heater (31), it is possible to suppress the temperature on the front side of the casing (11) from becoming excessively high.

When the fan (50) is operated, indoor air in the indoor space (S) is sucked into the suction port (20). This air flows upward through the first flow path (23). The air in the first flow path (23) is heated by the heat of the front heat-resistant glass (60) and the rear heat-resistant glass (61). The air flowing into the second flow path (25) via the communication path (24) is heated by the first heater (31) while flowing downward through the second flow path (25). The heated air passes through the fan (50) and is blown out from the air outlet (21) into the indoor space (S) as warm air.

In this way, in this example, air flows along the front surface of the rear heat-resistant glass (61) and the rear surface of the front heat-resistant glass (60) in the first flow path (23), so that the rear heat-resistant glass (61) and The heat absorbed by the front heat-resistant glass (60) can be used to heat the air. At the same time, since the rear heat-resistant glass (61) and the rear heat-resistant glass (61) can be cooled with air, it is possible to suppress the temperature on the front side of the casing (11) from becoming excessively high.

In particular, since the front heat-resistant glass (60) is exposed to the outside of the casing (11), if the surface temperature of the front heat-resistant glass (60) becomes too high, user safety will be compromised. On the other hand, in this embodiment, the surface temperature of the front heat-resistant glass (60) can be lowered, so the safety of the user can be ensured.

(12-5) Modification example 5
In the floor-standing heating device (10) of Modification Example 5 shown in FIG. 10, the position of the fan (50) is different from that of Modification Example 1 described above. The fan (50) is arranged above the first heater (31), which is the upper one of the two first heaters (31), in the air passage (P). The fan (50) is arranged at or near the upstream end of the second flow path (25). Also in this example, the reflection plate (40) is arranged so as to cross the shortest path connecting the first heater (31) and the fan (50).

The floor-standing heating device (10) of this example includes a second heater (33). The second heater (33) is, for example, an electric heater that generates heat when energized. The second heater (33) includes a thermoelectric element such as a thermistor or a Peltier element. The second heater (33) is arranged at the lower end of the second flow path (25). Specifically, the second heater (33) is arranged below the first heater (31), which is the lower one of the two first heaters (31).

The second heater (33) heats the air in the air passage (P). Specifically, the second heater (33) heats the air in the second flow path (25). In the floor-standing heating device (10) of this example, the fan (50) is arranged near the upper end of the casing (11), whereas the second heater (33) is arranged near the lower end of the casing (11). Ru. In this way, since the fan (50) is provided at a relatively distant position from the second heater (33), the influence of heat generated by the second heater (33) on the fan (50) is suppressed.

In the floor-standing heating device (10) of this example, by operating the first heater (31), second heater (33), and fan (50), the reflector (40) absorbs heat from the first heater (31). ) as it flows downward while being heated. The air that has passed through the lower end of the rear surface of the reflector (40) is further heated by passing through the second heater (33). In this way, the temperature of the hot air at the outlet (21) which is insufficient due to heating by the first heater (31) alone can be compensated for by heating by the second heater (33). Furthermore, by operating the second heater (33) and fan (50), it is possible to perform an operation in which only warm air is blown out from the outlet (21).

(13) Other Embodiments The above embodiment and each modification may have the following configurations.

The first curved surface portion (41) and the second curved surface portion (42) are determined by the presence or absence of the first sloped portion (R1) and the second sloped portion (R2), or the presence or absence of the first curved surface portion (41) and the second curved surface portion (42). ) may be formed so that the heat rays from the first heater (31) reflected by the reflection plate (40) travel substantially horizontally toward the front surface (12). This makes it possible to intensively heat the front of the front (12). In this case, the mounting angle of the first curved surface section (41) and the second curved surface section (42), which are formed so that the heat rays reflected by the reflector plate (40) proceed approximately horizontally toward the front surface (12), is determined. The heat rays reflected by the reflector (40) may be adjusted so as to travel upward toward the front surface (12) or may be directed downward.

Although the panel (60) of the present disclosure has been described as being formed in the front opening (11a) in the above embodiment, the panel (60) is formed inside the front opening (11a), that is, in the casing (11). It may be formed inside the front surface (12) or along the front surface (12) of the casing (11).

The panel (60) may be a heat-resistant film. A heat-resistant film may be provided to cover the front opening (11a).

Although the embodiments and modifications have been described above, it will be understood that various changes in form and details can be made without departing from the spirit and scope of the claims. Furthermore, the above embodiments and modifications may be combined or replaced as appropriate, as long as the functionality of the object of the present disclosure is not impaired. The descriptions of "first", "second", etc. mentioned above are used to distinguish the words to which these descriptions are given, and do not limit the number or order of the words. .

As described above, the present disclosure is useful for floor-standing heating devices.

11 Casing
12 Front
13 Rear
20 Suction port
21 Air outlet
25 Second flow path (first space)
31 1st heater
33 Second heater
40 Reflector
42 Second curved surface part (guide part)
50 fans
60 panels
P Air passage
R1 1st slope
R2 2nd slope
S Indoor space (target space)

Claims (6)

a casing (11) in which an internal space (I) is formed;
a first heater (31) disposed in the internal space (I) and providing radiant heat;
a reflecting plate (40) disposed in the internal space (I) and reflecting heat rays generated from the first heater (31) toward the front surface (12) of the casing (11);
a suction port (20) formed in the casing (11) and sucking air from the target space (S);
an air outlet (21) formed in the casing (11) and blowing air into the target space (S);
an air passage (P) provided in the internal space (I) and communicating with the suction port (20) and the blowout port (21);
a fan (50) arranged in the air passageway (P) and conveying air from the suction port (20) toward the blowout port (21);
a second heater (33) that heats the air in the air passageway (P);
The air passage (P) is formed so that air heated by the first heater (31) flows toward the fan (50),
The reflector (40) is arranged to cross the shortest path connecting the first heater (31) and the fan (50),
The second heater (33) is a floor-standing heating device disposed within the air passage (P) on the downstream side of the fan (50) in the air flow direction. The floor-standing heating device according to claim 1, wherein the fan (50) is arranged above the first heater (31) in the air passageway (P). The floor-standing heating device according to claim 2, wherein the second heater (33) is arranged below the first heater (31). The reflective plate (40) is
The floor-standing heater according to claim 1 , further comprising a first slope (R1) that slopes downward toward the front surface (12) so that the reflected heat rays travel upward toward the front surface (12). Device. The reflective plate (40) is
The floor-standing heater according to claim 1 , further comprising a second slope (R2) that slopes upward toward the front surface (12) so that the reflected heat rays travel downward toward the front surface (12). Device. The front surface (12) of the casing (11) includes a heat-resistant glass (60) that transmits heat rays from the first heater (31) and the suction port (20),
The air passage (P) has a first flow path (23) formed between the heat-resistant glass (60) and the reflection plate (40),
The floor-standing heating device according to claim 1, wherein the first flow path (23) faces the first heater (31).