JP2004176974A - Heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heater having high safety without dropping a broken piece of glass in a room even when a heater lamp bursts. <P>SOLUTION: This heater comprises a lighting fixture installed on the ceiling or a wall surface of the room to be heated, a bar-shaped heater lamp arranged in this lighting fixture, a gutter-shaped concave mirror arranged so as to surround the heater lamp under this heater lamp and emitting the light upward and a radiating mirror for reflecting and radiating the light from this concave mirror toward a space under the lighting fixture of the room. The concave mirror is composed of an elliptic mirror. The heater lamp is arranged in a first focal position of the elliptic mirror, and the radiating mirror is desirably arranged on the opposite side of the first focal position on a second focal position of the elliptic mirror. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a heating device that is attached to a ceiling or a wall surface of a room to be heated and that radiates light including heat rays from a heater lamp to heat the room.
[0002]
[Prior art]
Currently, various heating devices are used to heat a room. However, when a stove or a fan heater that burns gas or liquid fuel is used, there is a problem that indoor air is contaminated. .
As a device that does not have such a problem, a heating device that uses electric energy is also widely used. For example, heating is performed using light including a heat ray radiated from a heater lamp including a double-ended incandescent lamp. Devices and the like are known (for example, see Patent Document 1).
[0003]
This heating device is arranged on a ceiling of a room to be heated or a wall surface near the ceiling, and radiates light toward a lower indoor space to heat the room.
However, since such a heating device is configured to directly emit the radiated light from the heater lamp to the indoor space, if the incandescent lamp ruptures, glass fragments fall into the room. There is a problem that it is dangerous.
[0004]
[Patent Document 1]
JP-A-6-74467 [0005]
[Problems to be solved by the invention]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a heating device with high safety in which glass fragments do not fall into a room even when a heater lamp ruptures. It is in.
[0006]
[Means for Solving the Problems]
The heating device of the present invention is provided with a lamp mounted on a ceiling or a wall surface of a room to be heated, a rod-shaped heater lamp arranged in the lamp, and provided below the heater lamp so as to surround the heater lamp. And a radiation mirror for reflecting light from the concave mirror and radiating the light toward a space below the lamp in the room.
[0007]
In the heating device according to the present invention, the concave mirror comprises an elliptical mirror, the heater lamp is disposed at a position of a first focal point of the elliptical mirror, and the radiation mirror is disposed at a first focal point with respect to a position of a second focal point of the elliptical mirror. Is preferably arranged on the side opposite to the position.
[0008]
In the heating device of the present invention, it is preferable that an auxiliary mirror that receives light that is not directly incident on the radiation mirror and that reflects light toward the radiation mirror is provided among the light emitted from the heater lamp and the concave mirror.
[0009]
[Action]
According to the above configuration, since the lower part of the heater lamp is covered by the trough-shaped concave mirror that is curved while being opened upward, broken glass pieces are stored in the concave mirror even if the heater lamp is damaged. Because it is not dropped into the room, high security is obtained.
[0010]
Further, according to the configuration in which the radiation mirror is located at the position of the first focal point of the elliptical mirror and on the opposite side with respect to the position of the second focal point, light that is once condensed and then diffused is transmitted to the radiation mirror. Since the light is incident and reflected, overheating of the radiation mirror can be prevented, and light can be emitted over a wide area of the room to be heated, so that the heating effect can be reliably obtained.
[0011]
Further, according to the configuration in which the auxiliary mirror is provided, the light emitted from the heater lamp can be radiated into the room with high efficiency, so that the heating effect can be obtained with high energy efficiency and the lighting fixture can be used. Since the irradiation of light to the inner surface is prevented, the temperature rise of the lamp is suppressed, and the ceiling or the wall near the ceiling to which the heating device having the lamp is attached is prevented from being heated to cause a fire. .
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings.
<First embodiment>
FIG. 1 is an explanatory cross-sectional view schematically illustrating a configuration of a heating device according to an embodiment of the present invention.
In the heating device S of this example, a gutter-like shape having a rod-shaped heater lamp 12 and a light emission opening 13 for emitting light including a heat ray emitted from the heater lamp 12 upward in the lamp 10. A concave mirror 14 and a radiation mirror 16 that emits light from the concave mirror 14 toward a space below the lamp 10 are provided.
[0013]
The lighting device 10 is a box-shaped housing, and specifically, a back plate 10C that stands up, an upper plate 10A that extends forward from the upper side of the back plate 10C, and a front plate that extends forward from the lower side of the back plate 10C, A bottom plate 10B whose length is shorter than the top plate 10A, a short front plate 10D extending downward from the front edge of the top plate 10A, and right and left side plates (not shown) arranged on the left and right sides integrally. The light emitting opening 11 is formed in a front inclined surface 10E that is displaced forward as it goes upward between the front edge of the bottom plate 10B and the lower side of the front plate 10D. Is provided with a wire mesh.
[0014]
The heater lamp 12 is formed of a rod-shaped halogen incandescent lamp, and extends in a horizontal direction (a direction perpendicular to the paper surface in FIG. 1) in a lower portion of the lamp 10, and has sockets whose both ends are respectively installed on a right side plate and a left side plate. It is attached to.
[0015]
The halogen incandescent lamp constituting the heater lamp 12 includes, for example, a glass envelope sealed at both ends and a filament coil disposed in the envelope. Sandblasted to scatter light.
For example, a halogen incandescent lamp having a rated voltage of 100 V, a power consumption of 600 W, and a heating length of 450 mm is used.
[0016]
The concave mirror 14 is formed of an elliptical mirror having a gutter-like shape extending along a part of the ellipse and extending in a direction parallel to the heater lamp 12 so as to cover a lower portion of the heater lamp 12 with a gap therebetween. The first focal point F ₁ and the second focal point F ₂ are positioned on the optical axis that is displaced forward as going upward, and the heater is located at the position of the first focal point F ₁ located in the lower rear of the lamp 10. A lamp 12 is arranged.
[0017]
The concave mirror 14, on a plane extending in straight line connecting the first focal point F ₁ and a second focal point F ₂ in the vertical direction, in which the light-emitting opening 13 for emitting light is formed above.
[0018]
Radiation mirror 16, the lower surface is a flat mirror extending in the horizontal direction, which is a reflection surface, on the opposite side of the position of the heater lamp 12 with respect to the second position of the focal point F ₂ of the concave mirror 14, specifically, The lamp 10 is located at a front position along the lower surface of the upper plate 10A.
[0019]
As shown in FIG. 2, such a heating device S is attached to a ceiling 32 of a room R to be heated or a wall surface 36 near the ceiling 32. For example, the heating device S is attached to an upper plate 10A or a back plate 10C of the lamp 10. And a support member (not shown) for attaching to a ceiling or a wall surface.
Outside the lamp 10, a lighting device (not shown) including a switch for controlling turning on and off of the lamp is provided.
[0020]
In the above-mentioned heating device S, when the switch of the lighting device is turned on and the heater lamp 12 is turned on, the internal filament coil becomes incandescent, thereby emitting light including heat rays by infrared rays.
[0021]
The light including the heat ray emitted from the heater lamp 12 is emitted upward from the light emitting opening 13 directly or via the concave mirror 14, and the emitted light is incident on the radiation mirror 16 and reflected therefrom. As shown in (1), the light is radiated from the light emission opening 11 of the lamp 10 into the lower indoor space, and heating is performed.
[0022]
Since the lamp 10 is installed on the wall surface 36 near the ceiling 32 in the room R to be heated, the light radiated from the light emission opening 11 of the lamp 10 into the lower indoor space is emitted from the room R. By irradiating the floor surface 34, a heating effect is obtained in the room R.
[0023]
In this heating apparatus, since the lower part of the heater lamp 12 is covered by the gutter-shaped concave mirror 14, even if the heater lamp 12 is damaged, broken glass is accommodated in the concave mirror 14 and , And therefore, high security can be obtained.
[0024]
Also, after the radiation mirror 16, the heater lamp 12 positioned in the first position of the focal point F ₁ of the concave mirror 14, in order on the opposite side with respect to the second focal point F ₂ of the concave mirror 14, which was once condensing Since the diffused light is incident on the radiation mirror 16 and reflected, it is possible to prevent the radiation mirror 16 from being overheated, and to emit light for heating over a wide range of the room R to be heated. A heating effect can be obtained.
[0025]
<Second embodiment>
FIG. 3 is an explanatory cross-sectional view schematically illustrating a configuration of a heating device according to another embodiment of the present invention.
The heating device of this example has basically the same configuration as that of FIG. 1. Specifically, a rod-shaped heater lamp 22 similar to that of FIG. A trough-shaped concave mirror 24 having a light emission opening 23 for emitting light containing heat rays emitted from the upper side, and radiation for radiating light from the concave mirror 24 toward a space below the lamp 20. A mirror 26 is provided. Further, the rear assist which reflects the light not directly incident on the radiation mirror 26, that is, the light L ₁ traveling toward the back plate 20 C in the lamp 20 and the light L ₂ traveling forward in the lamp 20 toward the radiation mirror 26. A mirror 27 and a front auxiliary mirror 28 are provided.
Reference numeral 21 denotes a light emission opening for emitting light from the radiation mirror 26 to the outside of the lamp 20.
[0026]
The concave mirror 24 is, for example, the same as the concave mirror according to the first embodiment except that the front edge portion is removed from the concave mirror according to the first embodiment. .
[0027]
The rear auxiliary mirror 27 is composed of two flat mirrors, that is, an upper rear auxiliary mirror 27A and a lower rear auxiliary mirror 27B. The lower rear auxiliary mirror 27B has a lower edge on the rear edge of the concave mirror 24 (see FIG. The lower rear auxiliary mirror 27B has an upper edge connected to the lower end of the upper rear auxiliary mirror 27A, extends forward and inclines, and extends downward. It is connected to the rear end (left end in the figure).
[0028]
The front auxiliary mirror 28 is formed of a flat mirror, and is connected to the front edge (the right end in the figure) of the concave mirror 24 and extends upward.
[0029]
In this example, the horizontal distance D ₂ between the heater lamp 22 and the radiation mirror 26, there is a state of being smaller than the horizontal distance D ₁ of the first embodiment.
Here, "separation distance" is the vertical plane M ₁ passing through the central axis of the heater lamp, the distance between the vertical plane M ₂ passing through the (left end in FIGS. 1 and 3) the rear end of the radiating mirror.
[0030]
As described above, by the horizontal distance D ₂ between the heater lamp 22 and the radiation mirror 26 is a state of being smaller than the horizontal distance D _1, becomes lamp 20 is small.
[0031]
In this example, the light including the heat ray emitted from the heater lamp 22 is emitted upward from the light emission opening 23 directly or via the concave mirror 24, and a part thereof is directly incident on the emission mirror 26 and reflected. The light is emitted from the light emission opening 21 of the lamp 20 toward the lower space, and another part is once or twice through the upper rear auxiliary mirror 27A, the lower rear auxiliary mirror 27B, or the front auxiliary mirror 28. The light is reflected as described above, is incident on the radiation mirror 26, is reflected, and is radiated from the light radiation opening 21 of the lamp 20 to a space below.
[0032]
As described above, the light directly incident on the radiation mirror 26 from the light emission opening 23 and reflected is reflected via the auxiliary mirror including the upper rear auxiliary mirror 27A, the lower rear auxiliary mirror 27B, and the front auxiliary mirror 28. Since the light is superimposed and emitted downward from the light emission opening 21 of the lamp 20 via the emission mirror 26, the light emitted from the heater lamp 22 is emitted into the room with high efficiency to heat the indoor space. In addition, the irradiation of light to the inner surface of the lamp 20 is prevented, so that the temperature rise of the lamp 20 is suppressed, and as a result, the ceiling to which the lamp 20 is attached or the wall surface near the ceiling is heated. To prevent fire.
[0033]
Although the embodiments of the present invention have been specifically described above, the present invention is not limited to the above-described examples, and various changes can be made to the specific configuration of each unit.
For example, the radiation mirror is not limited to a flat mirror as long as the light from the heater lamp is incident and reflected, and is emitted to the space below the lamp, for example, a concave mirror is used. It may be something.
[0034]
In addition, the radiation mirror, the upper rear auxiliary mirror, the lower rear auxiliary mirror, the concave mirror, and the front auxiliary mirror may be integrally formed, and each has an independent structure that is not connected. Or a configuration in which some of the components are connected.
[0035]
Further, the bottom plate of the lamp may have a configuration in which a fan (not shown) for releasing heat generated in the lamp by the heater lamp into the room is provided. In this case, the provision of the fan prevents overheating of each member of the heating device, and releases the air warmed in the lamp into the room, thereby providing a heating effect with higher energy efficiency. Obtainable.
[0036]
【The invention's effect】
According to the heating device of the present invention, since the lower part of the heater lamp is covered by the trough-shaped concave mirror which is curved in an open state, even if the heater lamp is broken, the glass fragments are not reflected by the concave mirror. Since it is stored in a room and does not fall into the room, high security can be obtained.
[0037]
Further, according to the heating device of the present invention, since the radiation mirror has a configuration in which the heater lamp is located at the position of the first focal point of the elliptical mirror and is located on the opposite side with respect to the position of the second focal point of the elliptical mirror, Since the light that is once condensed and then diffused is incident on and reflected by the radiation mirror, it is possible to prevent overheating of the radiation mirror and emit light over a wide area of the room to be heated. A heating effect can be reliably obtained.
[0038]
Furthermore, according to the heating device of the present invention, since the auxiliary mirror is provided, the light radiated from the heater lamp can be radiated into the room with high efficiency. The effect can be obtained, and the temperature rise of the lamp is suppressed, and the ceiling or the wall near the ceiling to which the heating device having the lamp is attached is prevented from being heated and causing a fire.
[Brief description of the drawings]
FIG. 1 is an explanatory cross-sectional view schematically showing a configuration of a heating device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view showing a state where the heating device of FIG. 1 is installed indoors.
FIG. 3 is an explanatory sectional view schematically showing the configuration of a heating device according to another embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Lamp 10A Top plate 10B Bottom plate 10C Back plate 10D Front plate 10E Front inclined surface 11 Light emission opening 12 Heater lamp 13 Light emission opening 14 Concave mirror 16 Radiation mirror F ₁ First focus F ₂ Second focus 20 Light 20C Back plate 21 the light emission opening 22 heater lamp 23 light-emitting opening 24 concave mirror 26 the radiation mirror 27 behind the auxiliary mirror 27A upper rear auxiliary mirror 27B lower rear auxiliary mirror 28 forwardly auxiliary mirror _L 1, _{L 2} light _D 1, _{D 2} horizontal Direction separation distance M ₁ , M ₂ Vertical plane S Heating device R room 32 Ceiling 34 Floor surface 36 Wall surface

Claims (3)

A lamp mounted on the ceiling or wall of a room to be heated, a rod-shaped heater lamp disposed in the lamp, and a gutter-like shape provided below the heater lamp so as to surround the heater lamp and emit light upward. A concave mirror, and a radiation mirror that reflects light from the concave mirror and emits the light toward a space below the lamp in the room. The concave mirror comprises an elliptical mirror, the heater lamp is disposed at a position of a first focal point of the elliptical mirror, and the radiation mirror is disposed on a side opposite to the position of the first focal point with respect to the position of a second focal point of the elliptical mirror. The heating device according to claim 1, wherein The auxiliary mirror according to claim 1 or 2, further comprising an auxiliary mirror that receives light that is not directly incident on the radiation mirror and reflects the light toward the radiation mirror, out of the light emitted from the heater lamp and the concave mirror. A heating device as described.

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