JP2023082911A - Heating device - Google Patents

Abstract

To provide a heating device that can efficiently heat warm air to be supplied to a target space.SOLUTION: A heating device comprises a first plate (61) arranged behind a front surface (12) of a casing (11) and in front of a heater (31), and for absorbing heat transferring to the outside of the casing (11) from the heater (31). A first space (23) along a front surface of the first plate (61), and through which air to be supplied to a target space (S) outside the casing (11) flows is formed in an internal space (I) of the casing (11).SELECTED DRAWING: Figure 2

Description

The present disclosure relates to heating devices.

Patent Literature 1 discloses an electric stove. The electric stove includes a casing and a heater arranged inside the casing 10 . When the heater is energized, radiant heat is emitted toward the front of the stove to heat the room. A heat-resistant glass is provided in front of the heater.

JP-A-2000-314532

An electric heater such as that described in Patent Document 1 heats air sucked into a casing by a heater and supplies the air to a target space. Such warm air can promote heating of the target space. However, the electric heater disclosed in Patent Literature 1 does not sufficiently heat such hot air.

An object of the present disclosure is to provide a heating device capable of efficiently heating warm air supplied to a target space.

A first aspect comprises a casing (11) in which an internal space (I) is formed, a heater (31) arranged in the internal space (I), and a heater (31) located behind the front surface (12) of the casing (11). and a first plate (61) disposed in front of the heater (31) for absorbing heat transferred from the heater (31) to the outside of the casing (11). The space (I) defines a first space (23) along the front surface of the first plate (61) and through which air supplied to the target space (S) outside the casing (11) flows. .

In the first aspect, the first space (23) is formed along the front surface of the first plate (61) in the internal space (I) of the casing (11). When air flows through the first space (23), the heat absorbed by the first plate (61) is transferred to the air. Thereby, the air flowing through the first space (23) can be heated. The air heated in the first space (23) is supplied to the target space (S). As a result, the heating device (10) can recover the heat absorbed by the first plate (61) as the heat of the hot air supplied to the target space (S), so that the hot air can be efficiently heated. .

A first plate (61) is arranged in front of the heater (31), and the first plate (61) absorbs heat emitted from the heater (31), thereby excessively increasing the temperature of the front side of the casing (11). can be suppressed, and user safety can be ensured.

In the second aspect, in the first aspect, a second plate ( 60), wherein the first space (23) is formed between the first plate (61) and the second plate (60).

In the second aspect, when air flows through the first space (23), the heat absorbed by the first plate (61) and the second plate (60) is transferred to the air. Thereby, the air flowing through the first space (23) can be heated. The air heated in the first space (23) is supplied to the target space (S). As a result, the heating device (10) can recover the heat absorbed by the first plate (61) and the second plate (60) as the heat of the warm air, so that the warm air can be efficiently heated.

Since both the first plate (61) and the second plate (60) absorb the heat generated by the heater (31), the temperature on the front side of the casing (11) can be prevented from becoming excessively high. can ensure the safety of

According to a third aspect, in the second aspect, a second space (25) is formed behind the first plate (61) in the internal space (I) of the casing (11). The space (23) and the second space (25) are configured to allow the flow of air supplied to the target space (S).

In the third aspect, air flows through the first space (23) and the second space (25). The flow of air in the second space (25) allows the heat on the rear surface side of the first plate (61) to be transferred to the air in the second space (25). As a result, the heating device (10) can efficiently heat the air by the first plate (61).

In a fourth aspect based on the third aspect, the heater (31) is arranged in the second space (25), and the first space (23) has more airflow than the second space (25). is formed on the upstream side of the

In the fourth aspect, the air in the first space (23) is heated by the first plate (61) before being heated by the heater (31). Therefore, a sufficient temperature difference can be ensured between the air flowing through the first space (23) and the first plate (61). In addition, since the temperature of the heater (31) is sufficiently higher than the temperature of the first plate (61), a sufficient temperature difference is ensured between the air flowing through the second space (25) and the heater (31). can. As a result, the heating device (10) can efficiently heat the air in the first space (23) and the second space (25).

In a fifth aspect, in the first aspect, a suction port (20) is formed in one of the upper and lower front sides of the casing (11), and an outlet port (21) is formed in the other, and the first space One end of (23) is connected to the suction port (20), and the other end of the first space (23) is connected to the blowout port (21).

In the fifth aspect, the first space (23) is formed from the top to the bottom of the casing (11). Therefore, a relatively long passage length can be secured in the first space (23), so that the air can be efficiently heated by the first plate (61).

In a sixth aspect, in any one of the first to fourth aspects, the suction port (20) is formed on the rear side of the casing (11), and the air outlet (20) is formed on the front side of the casing (11). 21) is formed.

In the sixth aspect, it is possible to suppress so-called short circuit in which the air blown out from the blowout port (21) on the front side of the casing (11) is immediately sucked into the suction port (20).

According to a seventh aspect, in any one of the first to sixth aspects, a fan (50) for conveying air is provided, and the fan (50) is located below the inner space (I) of the casing (11). placed in

FIG. 1 is a schematic perspective view of a heating device according to an embodiment. Fig. 2 is a vertical cross-sectional view perpendicular to the left-right direction of the heating device FIG. 3 is a block diagram of the control unit. FIG. 4 is a diagram corresponding to FIG. 2 of Modification 1. As shown in FIG. FIG. 5 is a diagram corresponding to FIG. 2 of Modification 2. In FIG. FIG. 6 is a diagram corresponding to FIG. 2 of Modification 3. In FIG. FIG. 7 is a diagram corresponding to FIG. 2 of Modification 4. In FIG. FIG. 8 is a diagram corresponding to FIG. 2 of Modification 5. In FIG. FIG. 9 is a diagram corresponding to FIG. 2 of Modification 6. In FIG. FIG. 10 is a diagram corresponding to FIG. 2 of Modification 7. In FIG. FIG. 11 is a diagram corresponding to FIG. 2 of the eighth modification. FIG. 12 is a diagram corresponding to FIG. 2 of the ninth modification.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings. Note that the present disclosure is not limited to the embodiments shown below, and various modifications are possible without departing from the technical idea of the present disclosure. Each drawing is for the purpose of conceptually explaining the present disclosure, and therefore dimensions, ratios or numbers may be exaggerated or simplified as necessary for ease of understanding.

(1) Overview of Heating Device A heating device (10) according to an embodiment will be described with reference to FIGS. 1 and 2. FIG. In the following description, "up", "down", "front", "rear", "right", and "left" basically mean directions indicated by arrows in FIG.

A heating device (10) heats an indoor space (S), which is a target space. The heating device (10) is installed on the floor (F) of the indoor space (S). The heating device (10) heats the indoor space (S) with radiant heat. In addition, the heating device (10) of the present embodiment heats the indoor air in the indoor space (S) and supplies the heated air to the indoor space (S).

The heating device (10) comprises a casing (11), a heater element (30), a reflective element (40), a fan (50), a front heat-resistant glass (60) and a rear heat-resistant glass (61). I have. The heater element (30) emits far infrared rays (heat rays). The reflecting element (40) reflects heat rays emitted from the heater element (30) and guides them forward of the heating device (10). The front heat-resistant glass (60) and the rear heat-resistant glass (61) absorb heat generated by the heater element (30). The front heat-resistant glass (60) and the rear heat-resistant glass (61) function as heat absorbing plates or protective plates.

(2) Casing The casing (11) is formed in a hollow substantially rectangular parallelepiped shape. The casing (11) is made of, for example, a resin material. The casing (11) is shaped like a vertically long box. The casing (11) has six faces (12, 13, 14, 15, 16, 17). The six faces consist of a front face (12), a rear face (13), a top face (14), a bottom face (15), a right face (16) and a left face (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 upper side of the casing (11), and the bottom surface (15) is located on the upper side of the casing (11). ) is located below 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).

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 front heat-resistant glass (60) is provided in the front opening (11a). The front heat-resistant glass (60) is fixed to the casing (11) so as to block the front opening (11a).

As shown in FIGS. 1 and 2, the front surface (12) of the casing (11) is formed with an inlet (20) and an outlet (21). The suction port (20) is an opening for sucking air in the indoor space (S). The blowout port (21) is an opening for blowing out the air in the casing (11) into the room space (S). The inlet (20) and the outlet (21) are located at the bottom of the casing (11). Specifically, the outlet (21) is located at the lower end of the casing (11). The outlet (21) is positioned near the floor (F) of the indoor space (S). The blowout port (21) extends laterally from the right surface (16) to the left surface (17) of the casing (11). The suction port (20) is located above the outlet (21). The blowout port (21) extends left and right along the upper side of the suction port (20). An air passage (P) is formed in the internal space (I) of the casing (11) from the inlet (20) to the outlet (21).

(3) Heater element The heater element (30) of this embodiment has three heaters (31). The number of heaters (31) is merely exemplary and may be one, two, four or more. Each heater (31) is fixed to a heater support (not shown). The three heaters (31) are arranged behind the rear heat-resistant glass (61). The heater (31) has a far-infrared coating containing ceramic. Each heater (31) is formed in the shape of a pipe extending in the left-right direction or in the shape of a substantially bar. The three heaters (31) are arranged vertically along the front surface (12) and rear surface (13) of the casing (11). The three heaters (31) are arranged parallel to each other at regular intervals. Heat rays emitted from the heater (31) spread all around around the axial center of the heater (31).

(4) Reflective Element As shown in FIG. 2, the reflective element (40) of the present embodiment includes a rear reflector (41) and a front reflector (42).

The rear reflector (41) is arranged behind the heater (31) and the front reflector (42). The upper end of the rear reflector (41) is fixed to the casing (11) via the first support plate (35). A lower end of the rear reflector (41) is fixed to the casing (11) via the second support plate (36). The rear reflector (41) includes a substantially arcuate rear reflector (41a) in a cross-sectional view A perpendicular to the plane of FIG. 2 (horizontal direction). The rear reflecting portion (41a) extends in the left-right direction and has substantially the same cross-sectional shape in the left-right direction. Specifically, in cross-sectional view A, the rear reflecting portion (41a) is formed in a curved surface that bulges rearward. A first reflecting surface (R1) that reflects the heat rays of the heater (31) forward is formed on the front surface of the rear reflecting portion (41a).

The front reflector (42) is arranged between the heater (31) and the rear reflector (41). The upper end of the front reflector (42) is fixed to the rear reflector (41) via the third support plate (37). The lower end of the front reflector (42) is fixed to the rear reflector (41) via the fourth support plate (38). The front reflector (42), in cross-sectional view A, includes three substantially arc-shaped front reflectors (42a) and two connecting parts (42b) that connect them. Each front reflecting portion (42a) extends in the left-right direction and has substantially the same cross-sectional shape in the left-right direction. Specifically, each of the front reflecting portions (42a) is formed in a curved surface that bulges rearward in cross-sectional view A. As shown in FIG. Each front reflector (42a) is provided one by one corresponding to each heater (31). Each front reflector (42a) is located behind the corresponding heater (31) and opens toward the heater (31). A second reflecting surface (R2) is formed on the front surface of each front reflecting portion (42a) to reflect forward the heat rays of the corresponding heater (31). The connecting portion (42b) is formed in a plate-like shape extending in the left-right direction, and is formed continuously with two adjacent front reflecting portions (42a).

(5) Fan The fan (50) is an air blower that conveys the air in the air passage (P). The fan (50) of the present embodiment is a cross-flow fan. As schematically shown in FIG. 1, the fan (50) has a fan body (51) extending in the left-right direction and a fan motor (52) for rotating the fan body (51). The fan (50) is arranged below the internal space (I) of the casing (11). Specifically, the fan (50) is disposed downstream of the heater (31) in the air passage (P). The fan (50) is arranged near the outlet (21). Specifically, the shortest distance from the fan (50) to the outlet (21) is shorter than the shortest distance from the fan (50) to the heater (31).

(6) Front heat-resistant glass and rear heat-resistant glass The front heat-resistant glass (60) as the second plate is formed in a flat plate shape. The front heat-resistant glass (60) is provided in the front opening (11a) of the casing (11). A 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 laterally from the left surface (17) to the right surface (16) of the casing (11).

The front heat-resistant glass (60) is made of a glass material with excellent heat resistance. The front heat-resistant glass (60) has a property of transmitting far infrared rays emitted from the heater (31) and the reflectors (41, 42). On the other hand, the front heat-resistant glass (60) has the property of absorbing heat emitted from the heater (31) and the reflectors (41, 42).

The rear heat-resistant glass (61) as the first plate is formed in a flat plate shape. The rear heat-resistant glass (61) is arranged rearward of the front surface (12) of the casing (11) and forward of the heater (31). The rear heat-resistant glass (61) is arranged behind the front heat-resistant glass (60) with the first space (23) interposed therebetween. 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 substantially 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 the front heat-resistant glass (60) in the front-rear direction.

The rear heat-resistant glass (61) is made of the same material as the front heat-resistant glass (60). Specifically, the rear heat-resistant glass (61) is made of a glass material with excellent heat resistance. The front heat-resistant glass (60) has a property of transmitting far infrared rays emitted from the heater (31) and the reflectors (41, 42). In addition, the front heat-resistant glass (60) has the property of absorbing heat emitted from the heater (31) and the reflectors (41, 42). In the present embodiment, the thickness of the rear heat-resistant glass (61) in the front-rear direction is equal to the thickness of the front heat-resistant glass (60) in the front-rear direction.

(7) Air Passage The air passage (P) is formed continuously from the suction port (20) to the blowout port (21). The air passage (P) includes, in order from the upstream side to the downstream side of the air flow, a suction space (22), a first space (23), a communication passage (24), a second space (25), and a blowout space ( 26).

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

The first space (23) is connected to the downstream end of the suction space (22). A first space (23) is formed between the front heat-resistant glass (60) and the rear heat-resistant glass (61). Strictly speaking, the first space (23) is formed between the rear surface of the front heat-resistant glass (60) and the front surface of the rear heat-resistant glass (61). In other words, the rear surface of the front heat-resistant glass (60) and the front surface of the rear heat-resistant glass (61) are exposed to the first space (23). The first space (23) constitutes a channel through which air flows upward.

The second space (25) is formed behind the rear heat resistant glass (61). Strictly speaking, the second space (25) is formed between the rear surface of the rear heat resistant glass (61) and the front surface of the rear reflector (41). A heater (31) and a front reflector (42) are arranged in the second space (25). The second space (25) constitutes a channel through which air flows downward.

A communication path (24) is formed between the first space (23) and the second space (25). The communicating path (24) is formed above the rear heat-resistant glass (61). The communication path (24) connects the upstream end of the first space (23) and the downstream end of the second space (25). In the communication passage (24), the upward airflow makes a U-turn and becomes a downward airflow.

The blowout space (26) is connected to the upstream end of the blowout port (21). The blowout space (26) is formed on the far side (rear side) of the blowout port (21). A fan (50) is arranged in the blowing space (26).

(8) Control Section As shown in FIG. 3, the heating device (10) includes a control section (C). The control section (C) controls the fan motor (52) and the heater (31). Specifically, the control section (C) controls ON/OFF of the fan motor (52) and the number of revolutions of the fan motor (52). The controller (C) controls ON/OFF of the heater (31) and the output of the heater (31).

(9) Operating Behavior The operating behavior of the heating device (10) will be described with reference to FIGS. 1 and 2. FIG. When the heating device (10) is in operation, the controller (C) energizes the heater (31) and operates the fan (50).

When the heater (31) is energized, hot wire is emitted from the heater (31). A part of the heat rays emitted from the heater (31) directly moves forward. The rest of the heat rays emitted from the heater (31) indirectly travel forward after being reflected by the front reflector (42) and the rear reflector (41). As a result, radiant heat is released to the front side of the casing (11).

Here, when the heat emitted from the heater (31) passes through the rear heat-resistant glass (61), the heat is absorbed by the rear heat-resistant glass (61). Next, when the heat transmitted through the rear heat-resistant glass (61) is transmitted through the front heat-resistant glass (60), the heat is absorbed by the front heat-resistant glass (60). By providing the rear heat-resistant glass (61) and the front heat-resistant glass (60) in front of the heater (31) in this way, it is possible to prevent the temperature of the front side of the casing (11) from becoming excessively high.

On the other hand, when the fan (50) is operated, indoor air in the indoor space (S) is sucked into the suction port (20). This air passes through the suction space (22) and flows upward through the first space (23). When the air flows through the first space (23), the heat of the rear heat-resistant glass (61) is applied to the air. This heats the air in the first space (23). When the air flows through the first space (23), the heat of the front heat-resistant glass (60) is applied to the air. This heats the air in the first space (23). Thus, in the first space (23), the air flows along the front surface of the rear heat-resistant glass (61) and the rear surface of the front heat-resistant glass (60), so that the rear heat-resistant glass (61) and the front heat-resistant glass (60) The heat absorbed in (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 by air, it is possible to prevent the temperature of 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, the user's safety is compromised. In contrast, in the present embodiment, the surface temperature of the front heat-resistant glass (60) can be lowered, thereby ensuring the safety of the user.

Air before passing through the heater (31) flows in the first space (23). As a result, the temperature difference between the front heat-resistant glass (60) and the air becomes relatively large, and the amount of heat transferred from the front heat-resistant glass (60) to the air increases. In addition, since the temperature difference between the rear heat-resistant glass (61) and the air becomes relatively large, the amount of heat transferred from the rear heat-resistant glass (61) to the air increases. As a result, in the first space (23), the air can be efficiently heated, and the front heat-resistant glass (60) and the rear heat-resistant glass (61) can be efficiently cooled.

The air flowing upward in the first space (23) turns downward in the communication passage (24) and then flows through the second space (25). In the second space (25), the air is heated by the heater (31) to raise the temperature of the air. Air in the second space (25) flows along the rear surface of the rear heat-resistant glass (61). Therefore, the heat of the rear heat-resistant glass (61) can be applied to the air. Thus, in the second space (25), the air can be heated by the heater (31) and the rear heat resistant glass (61).

The air heated in the second space (25) flows through the blowout space (26), passes through the fan (50), and is blown out from the blowout port (21) into the indoor space (S). By blowing hot air from the air outlet (21), the indoor space (S) can be heated not only by the radiant heat from the front heat-resistant glass (60) but also by the hot air from the air outlet (21). The blowout port (21) is located below the casing (11). Specifically, the outlet (21) is positioned along the floor (F). Therefore, warm air can be blown out to the user's feet, and the user's comfort can be improved.

(10) Features (10-1)
The heating device (10) of the embodiment is arranged rearward of the front surface (12) of the casing (11) and forward of the heater (31), and absorbs heat moving from the heater (31) to the outside of the front casing (11). It has a rear heat-resistant glass (61) that absorbs the The interior space (I) of the casing (11) defines a first space (23) along the rear heat-resistant glass (61) and through which air supplied to the interior space (S) flows.

With this configuration, air flows through the first space (23) and can be heated by the rear heat-resistant glass (61). Therefore, the heating device (10) can supply the indoor space (S) with warm air that has recovered the heat absorbed from the rear heat-resistant glass (61), so that the air supplied to the indoor space (S) can be efficiently heated. can do.

Since the rear heat-resistant glass (61) can absorb the heat generated by the heater (31) and is cooled by the air flowing through the first space (23), it prevents the temperature on the front side of the casing (11) from becoming excessively high. It can be controlled and user safety can be ensured.

(10-2)
The heating device (10) includes a front heat-resistant glass (60) arranged in front of the rear heat-resistant glass (61) and absorbing heat transferred from the heater (31) to the outside of the casing (11). The first space (23) is formed between the rear heat-resistant glass (61) and the front heat-resistant glass (60).

With this configuration, the air flows through the first space (23) and can be heated by the rear heat-resistant glass (61) and the front heat-resistant glass (60). Therefore, the heating device (10) can supply warm air, which is obtained by recovering heat from the rear heat-resistant glass (61) and the front heat-resistant glass (60), to the indoor space (S). can be efficiently heated.

Since the heat generated from the heater (31) can be absorbed by the rear heat-resistant glass (61) and the front heat-resistant glass (60), it is possible to prevent the temperature of the front side of the casing (11) from becoming excessively high. Conversely, the rear heat-resistant glass (61) and the front heat-resistant glass (60) are cooled by the air flowing through the first space (23), thereby preventing the temperature on the front side of the casing (11) from becoming excessively high. can. The front heat-resistant glass (60) is exposed to the indoor space (S), but its surface temperature does not rise so much. Therefore, user safety can be ensured.

(10-3)
A second space (25) is formed behind the rear heat-resistant glass (61) in the internal space (I) of the casing (11). Air supplied to the indoor space (S) flows through the first space (23) and the second space (25). Therefore, the rear heat-resistant glass (61) can be cooled by the air flowing through the second space (25). Conversely, since the air flowing through the second space (25) can be heated by the rear heat-resistant glass (61), the amount of heat that can be recovered from the rear heat-resistant glass (61) can be increased.

(10-4)
A heater (31) is arranged in the second space (25). The first space (23) is formed upstream of the air flow relative to the second space (25). Therefore, in the first space (23), the temperature difference between the air and the rear heat-resistant glass (61) increases, thereby promoting heat transfer between the two. Similarly, in the first space (23), the temperature difference between the air and the front heat-resistant glass (60) increases, thereby promoting heat transfer between the two. This effectively prevents the temperature on the front side of the casing (11) from becoming excessively high. In addition, the amount of heat recovered by the warm air supplied to the indoor space (S) can be increased.

(11) Modifications The above embodiment may be modified as follows. Differences from the above embodiment will be mainly described below.

(11-1) Modification 1
In a heating device (10) of Modification 1 shown in FIG. 4, an air outlet (21) and an air inlet (20) are formed in the upper part of a casing (11). The blowout port (21) is formed above the suction port (20) at the upper end of the front surface (12) of the casing (11).

The front heat-resistant glass (60) is provided in the front opening (11a) below the suction port (20). A first space (23) is formed between the front heat-resistant glass (60) and the rear heat-resistant glass (61). The first space (23) constitutes a channel through which air flows downward. A communication path (24) is formed at the lower end of the rear heat-resistant glass (61).

The front reflector (42) includes three front reflectors (42a). The three front reflectors (42a) are positioned in front of the corresponding heaters (31). Each front reflecting portion (42a) is formed in an arc shape that bulges forward in cross-sectional view A. As shown in FIG. Each front reflector (42a) opens rearward toward the corresponding heater (31).

The second space (25) is formed between the rear heat resistant glass (61) and the front reflector (42). The second space (25) communicates with the first space (23) through the communication path (24). The second space (25) constitutes a channel through which air flows upward. The three heaters (31) are arranged between the front reflector (42) and the rear reflector (41).

A third space (27) through which air can flow is formed between the front reflector (42) and the rear reflector (41). The inflow end of the third space (27) communicates with the inflow end of the second space (25). The outflow end of the third space (27) communicates with the outflow end of the second space (25).

The fan (50) is arranged below the internal space (I) of the casing (11). The fan (50) is arranged near the communication path (24).

During operation of the heating device (10), heat rays from the heater (31) are reflected by the front reflector (42) and the rear reflector (41), and finally move forward of the casing (11), as in the embodiment. do. The heat of the heater (31) is absorbed by the rear heat-resistant glass (61) and the front heat-resistant glass (60).

Air sucked from the indoor space (S) into the suction port (20) flows downward through the first space (23). This air is heated by the front heat resistant glass (60) and the rear heat resistant glass (61). In other words, the air in the first space (23) cools the front heat-resistant glass (60) and the rear heat-resistant glass (61).

Air passing through the communication passage (24) flows through the second space (25) and the third space (27). The air flowing upward in the second space (25) is heated by the rear heat-resistant glass (61) and the front reflector (42). Air flowing through the third space (27) is mainly heated by the heater (31). The air in the third space (27) merges with the air in the second space (25) and is then blown out from the outlet (21) into the indoor space (S). In Modification 1, hot air is blown out from a relatively high position in the casing (11).

In the heating device (10) of Modification 1, the air does not have to flow through the 3rd space (27), and the heater (31) may be arranged in the 2nd space (25).

(11-2) Modification 2
In the heating device (10) of Modification 2 shown in FIG. 5, a relatively large outlet (21) is formed in the front surface (12) of the casing (11). The blowout port (21) extends from the upper end of the casing (11) to the lower portion of the casing (11). The suction port (20) is formed below the outlet port (21) at the lower end of the front surface (12) of the casing (11). The heating device (10) of Modification 2 does not have the front heat-resistant glass (60). The heating device (10) has a suction member (62) with a plurality of holes (H). The suction member (62) is composed of a mesh member or a punching plate. The suction member (62) is provided in the suction port (20) along the front surface (12) of the casing (11).

In Modification 2, the first space (23) is formed between the suction member (62) and the rear heat-resistant glass (61). The first space (23) is formed along the rear surface of the suction member (62) and the front surface of the rear heat resistant glass (61). The first space (23) constitutes a channel through which air flows upward.

The heating device (10) of Modification 2 does not have the rear reflector (41). A fourth space (28) in which the heater element (30) is arranged is formed between the rear heat resistant glass (61) and the front reflector (42). The fourth space (28) is a space through which air does not substantially flow. The second space (25) of Modification 2 is formed behind the rear heat-resistant glass (61). Strictly speaking, the second space (25) is formed between the front reflector (42) and the rear surface (13) of the casing (11). The second space (25) communicates with the first space (23) via the communication path (24). The rear surface of the front reflector (42) is exposed in the second space (25).

The fan (50) is arranged below the internal space (I) of the casing (11). The fan (50) is arranged in the blowout space (26) on the far side (rear side) of the blowout port (21).

During operation of the heating device (10), heat rays from the heater (31) are reflected by the front reflector (42) and finally move forward of the casing (11), as in the embodiment. The heat of the heater (31) is absorbed by the rear heat-resistant glass (61).

Air drawn into the suction port (20) from the indoor space (S) flows upward through the first space (23) after passing through the plurality of holes (H) of the suction member (62). This air is heated by the rear heat resistant glass (61). In other words, the air in the first space (23) cools the rear heat resistant glass (61).

The air that has passed through the communication passage (24) flows downward through the second space (25). This air is heated by the front reflector (42) that has absorbed the heat of the heater (31). The air heated by the rear heat-resistant glass (61) and the front reflector (42) as described above is blown out from the outlet (21) into the indoor space (S).

(11-3) Modification 3
In the heating device (10) of Modification 3 shown in FIG. 6, the rear suction port (71) is formed in the rear surface (13) of the casing (11) in the above-described embodiment. The rear suction port (71) is formed at the lower end of the rear surface (13) of the casing (11). The rear suction port (71) communicates with the blowout space (26) through the rear passageway (72).

In the heating device (10) of Modified Example 3, the fan (50) operates so that the air behind the heating device (10) in the indoor space (S) flows through the rear suction port (71). It is sucked into the rear passageway (72). This air passes through the fan motor (52). This air has a relatively low temperature compared to the air flowing through the second space (25). Therefore, the fan motor (52) can be cooled by the air sucked from the rear suction port (71).

(11-4) Modification 4
In a heating device (10) of Modified Example 4 shown in FIG. 7, a suction port (20) is formed in one of upper and lower front sides of a casing (11), and an outlet port (21) is formed in the other. Specifically, a suction port (20) is formed at the upper end of the front surface (12) of the casing (11), and an outlet port (21) is formed at the lower end of the front surface (12) of the casing (11). One end (upper end) of the first space (23) is connected to the suction port (20), and the other end (lower end) of the first space (23) is connected to the outlet (21). The fan (50) is arranged on the far side (rear side) of the outlet (21). In Modification 4, the air passage (P) is formed linearly from the upper end to the lower end of the casing (11). As a result, the length of the air passage (P) can be shortened, and the power of the fan (50) can be reduced.

In addition, in Modification 4, the positions of the inlet (20) and the outlet (21) are relatively distant. Therefore, so-called short circuit can be suppressed. A short circuit is a phenomenon in which the hot air blown out from the air outlet (21) is immediately sucked into the air inlet (20).

(11-5) Modification 5
In a heating device (10) of Modified Example 5 shown in FIG. 8, an inlet (20) is formed in one of upper and lower front sides of a casing (11), and an outlet (21) is formed in the other. Specifically, an air outlet (21) is formed at the upper end of the front surface (12) of the casing (11), and a suction port (20) is formed at the lower end of the front surface (12) of the casing (11). One end (upper end) of the first space (23) is connected to the outlet (21), and the other end (lower end) of the first space (23) is connected to the suction port (20). The fan (50) is arranged on the far side (rear side) of the suction port (20). The fan (50) may be arranged on the far side (rear side) of the air outlet (21) in the air passage (P). In Modification 5, the air passage (P) is formed linearly from the upper end to the lower end of the casing (11). As a result, the length of the air passage (P) can be shortened, and the power of the fan (50) can be reduced.

In addition, in Modification 5, as in Modification 4, the positions of the suction port (20) and the blowout port (21) are relatively distant. Therefore, so-called short circuit can be suppressed.

(11-6) Modification 6
The heating device (10) of Modified Example 6 shown in FIG. 9 has an upper opening (73) at the upper end of the front surface (12) of the casing (11) and a lower opening at the lower end of the front surface (12) of the casing (11). (74) is formed. One end (upper end) of the first space (23) connects with the upper opening (73), and the other end (lower end) of the first space (23) connects with the lower opening (74). The heating device (10) of Modification 6 has a first fan (50A) and a second fan (50B). The first fan (50A) is arranged on the far side (rear side) of the lower opening (74). The second fan (50B) is arranged on the far side (rear side) of the upper opening (73). The first fan (50A) blows upward the air sucked through the lower opening (74). The second fan (50B) blows downward the air sucked through the upper opening (73). The first fan (50A) and the second fan (50B) constitute a backflow forming mechanism that reverses the flow of air in the air passage (P).

Specifically, in the first operation, the control section (C) operates the first fan (50A) and stops the second fan (50B). In the first operation, the lower opening (74) functions as a suction port and the upper opening (73) functions as a blowout port. Room air sucked through the lower opening (74) flows upward through the first space (23) (see the solid line arrow in FIG. 9). This air is supplied to the indoor space (S) through the upper opening (73). Therefore, in the first operation, hot air can be supplied to a relatively high position in the indoor space (S).

In the second operation, the control section (C) stops the first fan (50A) and operates the second fan (50B). In the second action, the upper opening (73) functions as a suction port and the lower opening (74) functions as a blowout port. Room air sucked through the upper opening (73) flows downward through the first space (23) (see the dashed arrow in FIG. 9). This air is supplied to the indoor space (S) through the lower opening (74). Therefore, in the second operation, warm air can be supplied to a relatively low position in the indoor space (S). Specifically, warm air can be supplied to the feet of the user.

The backflow forming mechanism may be one fan arranged in the air passage (P) and a control device for reversing the rotation direction of this fan. Alternatively, the reverse flow forming mechanism may be one fan arranged in the air passage (P) and a passage switching mechanism that switches the passage so as to reverse the air flow in the air passage (P).

(11-7) Modification 7
In the heating device (10) of Modification 7 shown in FIG. 10, the first space (23) and the second space (25) are connected in parallel. In this example, a suction port (20) is formed at the upper end of the front surface (12) of the casing (11), and a suction space (22) is formed on the far side thereof. A blowout port (21) is formed at the lower end of the front surface (12) of the casing (11), and a blowout space (26) is formed on the back side thereof. The fan (50) is arranged on the far side (rear side) of the outlet (21).

Both the inflow end of the first space (23) and the inflow end of the second space (25) are connected to the suction space (22). Both the outflow end of the first space (23) and the outflow end of the second space (25) are connected to the blowout space (26).

The air sucked through the suction port (20) is divided into the first space (23) and the second space (25). The air that has flowed downward through the first space (23) and the air that has flowed downward through the second space (25) join in the blowout space (26), and then flow through the blowout port (21) into the interior space (S). supplied.

In Modified Example 7, the flow velocity of the air flowing through the first space (23) is reduced. Also, the temperature difference between the air flowing through the first space (23) and the front heat-resistant glass (60) and the rear heat-resistant glass (61) becomes relatively large. As a result, the amount of heat transferred from the front heat-resistant glass (60) and the rear heat-resistant glass (61) to the air in the first space (23) can be increased.

In Modified Example 7, the flow velocity of the air flowing through the second space (25) is reduced. Also, the temperature difference between the air flowing through the second space (25) and the rear heat-resistant glass (61) becomes relatively large. As a result, the amount of heat transferred from the rear heat resistant glass (61) to the air in the second space (25) can be increased.

In addition, the heater (31) may be arranged in the second space (25) in the heating device (10) of the seventh modification.

(11-8) Modification 8
In a heating device (10) of Modified Example 8 shown in FIG. 11, a blowout port (21) is formed in the front surface (12) of a casing (11), and a suction port (20) is formed in the rear surface (13) of the casing (11). It is formed. In this example, an outlet (21) is formed at the lower end of the front surface (12) of the casing (11). A suction port (20) is formed at the upper end of the rear surface (13) of the casing (11). An upper communication passageway (75) that is part of the air passageway (P) is formed in the lower portion of the internal space (I) of the casing (11). The upper communication passageway (75) is formed along the upper surface (14) of the casing (11). An inflow end (rear end) of the upper communication passageway (75) is connected to the suction port (20). The outflow end (front end) of the upper communication passageway (75) is connected to the inflow end (upper end) of the first space (23). An outflow end (lower end) of the first space (23) communicates with the outlet (21). The fan (50) is arranged on the far side (rear side) of the outlet (21).

In Modification 8, room air behind the casing (11) in the room space (S) is sucked into the suction port (20). This air sequentially flows through the upper communication passageway (75) and the first space (23), and is blown out from the outlet (21) into the indoor space (S).

By forming the suction port (20) on the rear surface (13) and forming the blowout port (21) on the front surface (12), the positions of the suction port (20) and the blowout port (21) become distant. As a result, the aforementioned short circuit can be suppressed. In particular, one of the suction port (20) and the blowout port (21) (the suction port (20) in this example) is formed at the upper end of the casing (11), and the other (the blowout port (21) in this example) is formed at the upper end of the casing (11). is formed at the lower end of the casing (11), the positions of the suction port (20) and the blowout port (21) can be made farther apart. As a result, short circuit can be effectively suppressed.

(11-9) Modification 9
In a heating device (10) of Modified Example 9 shown in FIG. 12, an outlet (21) is formed in the front surface (12) of the casing (11), and an intake port (20) is formed in the rear surface (13) of the casing (11). It is formed. In this example, an outlet (21) is formed at the upper end of the front surface (12) of the casing (11). A suction port (20) is formed at the lower end of the rear surface (13) of the casing (11). A lower communication passageway (76) that is part of the air passageway (P) is formed in the lower portion of the internal space (I) of the casing (11). A lower communication passageway (76) is formed along the lower surface (15) of the casing (11). An inflow end (rear end) of the lower communication passageway (76) is connected to the suction port (20). The outflow end (front end) of the lower communication passageway (76) is connected to the inflow end (lower end) of the first space (23). An outflow end (upper end) of the first space (23) communicates with the outlet (21). The fan (50) is arranged, for example, below the first space (23).

In the ninth modification, room air behind the casing (11) in the room space (S) is sucked into the suction port (20). This air sequentially flows through the lower communication passageway (76) and the first space (23), and is blown out from the outlet (21) into the indoor space (S).

By forming the suction port (20) on the rear surface (13) and forming the discharge port (21) on the front surface (12), the positions of the suction port (20) and the discharge port (21) become distant. As a result, the aforementioned short circuit can be suppressed. In particular, one of the suction port (20) and the blowout port (21) (the blowout port (21) in this example) is formed at the upper end of the casing (11), and the other (the suction port (20) in this example) is formed at the upper end of the casing (11). is formed at the lower end of the casing (11), the positions of the suction port (20) and the blowout port (21) can be made farther apart. As a result, short circuit can be effectively suppressed.

(12) Other Embodiments The above embodiments and modifications may be configured as follows.

In the above embodiment, the first plate and the second plate are made of heat-resistant glass. good. The first plate and the second plate preferably have heat resistance.

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

A heat-resistant film may be employed instead of the second plate. In this case, the heating device (10) may form the first space (23) between the heat-resistant film and the first plate.

The heating device (10) may not be a floor-mounted type, and may be a wall-mounted type.

Although embodiments and variations have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims. Moreover, the elements of the above embodiments, modifications, and other embodiments may be appropriately combined or replaced.

The descriptions of "first", "second", "third", etc. described above are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. not something to do.

INDUSTRIAL APPLICABILITY As described above, the present disclosure is useful for heating devices.

10 heating device
11 Casing
12 Front
20 suction port
21 outlet
23 first space
25 Second space
31 heater
50 fans
60 front heat-resistant glass (second plate)
61 Rear heat-resistant glass (first plate)

Claims (7)

a casing (11) in which an internal space (I) is formed;
a heater (31) arranged in the internal space (I);
A first plate ( 61) and
In the internal space (I) of the casing (11), a first space flows along the front surface of the first plate (61) and is supplied to the target space (S) outside the casing (11). (23) is formed heating system. a second plate (60) arranged in front of the first plate (61) and absorbing heat transferred from the heater (31) to the outside of the casing (11);
The heating device according to claim 1, wherein the first space (23) is formed between the first plate (61) and the second plate (60). A second space (25) is formed behind the first plate (61) in the internal space (I) of the casing (11),
The heating device according to claim 2, wherein the first space (23) and the second space (25) are configured so that the air supplied to the target space (S) flows. The heater (31) is arranged in the second space (25),
The heating device according to claim 3, wherein the first space (23) is formed upstream of the air flow relative to the second space (25). An inlet (20) is formed in one of upper and lower front sides of the casing (11), and an outlet (21) is formed in the other,
The heating device according to claim 4, wherein one end of the first space (23) is connected to the suction port (20), and the other end of the first space (23) is connected to the outlet (21). The suction port (20) is formed on the rear side of the casing (11), and the outlet port (21) is formed on the front side of the casing (11), according to any one of claims 1 to 4. heating system. Equipped with a fan (50) to convey the air,
The heating device according to any one of claims 1 to 6, wherein the fan (50) is arranged below the casing (11).

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