JP7002761B2 - Heating equipment - Google Patents

Description

The present embodiment relates to a heating device.

Conventionally, there is a heating device that drives a fan to heat air taken in from the outside by using a ceramic heater and blows it out as warm air. The heating device includes a fan case that houses the fan and guides the air diffused radially by the fan to a ceramic heater installed near the hot air outlet. Here, the direction in which the air is diffused by the fan and the direction in which the warm air is blown out are different. Therefore, a part of the fan case has a curved cross section that changes the traveling direction of the air from the diffusion direction of the air to the blowing direction of the warm air.

Jikkenhei 3-124164 Gazette

In the curved cross-section fan case, the volume of the air flow space is set to be approximately the minimum. Therefore, for example, it is difficult to increase the amount of air that can be blown while maintaining the shape of the fan case.

The present embodiment provides a heating device that is advantageous for increasing the air volume.

The heating device according to the present embodiment includes a housing, a fan installed inside the housing, a fan that takes in external air, a heating device that heats the air taken in by the fan, and air heated by the heating device. It is provided with a duct having a blowout portion that blows out to the outside, an introduction port that introduces air taken in by the fan, and an outlet that draws out the air introduced from the introduction port toward the blowout portion. It includes a rectangular first surface having two first side surfaces on which an opening surface is projected and two second side surfaces on which an opening surface of an outlet is projected.

According to the present embodiment, it is possible to provide a heating device which is advantageous for increasing the air volume.

It is a perspective view of the heating device which concerns on this embodiment. It is a side view of the heating device which concerns on this embodiment. It is a front view of the heating device which concerns on this embodiment. It is a rear view of the heating device which concerns on this embodiment. It is an exploded perspective view of the heating device which concerns on this embodiment. It is sectional drawing which cut in the XZ plane of the heating apparatus which concerns on this embodiment. It is a perspective view of the heating apparatus which concerns on this embodiment with the main body case removed. It is an enlarged sectional view explaining the space shape in a duct. It is sectional drawing which cut in the XY plane of the heating apparatus which concerns on this embodiment. It is a perspective view of the heating device which concerns on another embodiment. It is a side view of the heating device which concerns on another embodiment. It is a front view of the heating device which concerns on another embodiment. It is a rear view of the heating device which concerns on another embodiment. It is a top view of the heating apparatus which concerns on another embodiment. It is sectional drawing which cut in the XZ plane of the heating apparatus which concerns on another embodiment. It is an enlarged perspective view of the main body case explaining the intake port of a heating device. It is an enlarged perspective view of the front panel explaining the outlet of a heating device.

Hereinafter, the present embodiment will be described in detail with reference to the drawings. Here, the dimensions, materials, and other specific numerical values shown in the embodiment are merely examples, and the present embodiment is not limited unless otherwise specified. Further, elements having substantially the same function and configuration are designated by the same reference numerals to omit duplicate explanations, and elements not directly related to the present embodiment are not shown.

FIG. 1 is a perspective view showing the appearance of the heating device 1 according to the present embodiment. FIG. 2 is a side view of the heating device 1. FIG. 3 is a front view of the heating device 1. FIG. 4 is a rear view of the heating device 1. In each figure below FIG. 1, the height direction of the heating device 1 is defined as the Z direction. The Z direction may be along the vertical direction or may have an inclination with respect to the vertical direction. Further, in the plane perpendicular to the Z direction, the X direction and the Y direction perpendicular to the X direction are defined. In the present embodiment, it is assumed that the blowing direction of the warm air is approximately along the X direction. Hereinafter, in the X direction, the side that blows out warm air may be expressed as "front", and the opposite side may be expressed as "rear".

The heating device 1 is installed in a room, for example, and heats the room by heating the air taken in from the outside and blowing out warm air from the outlet 14a. In FIG. 1, the state in which warm air is blown from the heating device 1 is indicated by an arrow. The heating device 1 is a so-called vertical installation type in which the heating device 1 is placed on the floor surface, which is the installation surface, and stands upright in a used state. Further, the heating device 1 has a shape in which the side width along the X direction is narrower than the front width along the Y direction, that is, the width in the front-rear direction is thin.

The heating device 1 includes a main body case 10, a front panel 12, a guard 14, and an operation panel 16. Here, the housing 2 of the heating device 1 is a combination of the main body case 10 and the front panel 12.

The main body case 10 accommodates each of the other elements included in the heating device 1. The main body case 10 has a box shape whose front side is open with the case outer frame end 10a (see FIG. 6) as a boundary as a whole. As shown in FIG. 4, the main body case 10 has an intake port 10b that opens rearward. The main body case 10 has a base 18 on the lower surface portion 10d (see FIG. 5 and the like) for stably mounting the heating device 1 on the floor surface. The intake port 10b and the base 18 will be described in detail below. Further, the main body case 10 has a recess 10i for leading the power cord 54 to the outside.

The front panel 12 is located in front of the heating device 1 and covers the open surface of the main body case 10. The front panel 12 is removable with respect to the main body case 10. The front panel 12 has a panel outer frame end 12a (see FIG. 6) having a shape that matches the case outer frame end 10a of the main body case 10. That is, in a state where the front panel 12 is attached to the main body case 10, the panel outer frame end 12a and the case outer frame end 10a are combined. The front panel 12 is fixed to the main body case 10 using a plurality of mounting screws 13 (see FIG. 5). In FIG. 5, only one mounting screw 13 is drawn as an example. In this case, the main body case 10 has a plurality of through holes 10j through which the mounting screws 13 are passed. On the other hand, the front panel 12 has a plurality of screw hole portions 12b (see FIG. 7) corresponding to each of the plurality of through holes 10j. Further, the front panel 12 has a blowing portion 12c, a guard accommodating portion 12d, and a sensor window 12e.

The blowing portion 12c is a hole portion penetrating between the front surface side and the rear surface side. The warm air generated inside the heating device 1 is finally guided to the blowing portion 12c. In the present embodiment, the blowout portion 12c is provided on the lower side of the front panel 12.

The guard 14 has an outlet 14a for blowing out warm air generated inside the heating device 1 to the outside. The guard 14 is a protective member having a plurality of fins 14b in front of the outlet 14a for suppressing access to the outlet 14a from the outside. The plurality of fins 14b are arranged in parallel while maintaining the interval G1 so that a space penetrating in the X direction is formed. By appropriately setting the distance G1 between the fins 14b in advance, the guard 14 can suppress the access from the outside to the outlet 14a and can rectify the warm air. The guard 14 is made of a heat-resistant resin. The guard 14 is provided with a blowout port 14a near the lower end, and is not provided with a blowout port at the remaining portion near the upper end. As a result, it is possible to prevent the front panel 12 from being deformed by the heat of the warm air from the outlet 14a.

The guard accommodating portion 12d is a recess for accommodating and installing the guard 14 from the front side. When the guard 14 is installed in the guard accommodating portion 12d, the blowout port 14a of the guard 14 penetrates the blowout portion 12c formed in the front panel 12. Then, the opening end on the upstream side of the outlet 14a is connected to the outlet 64 of the duct 60 (see FIG. 6). Further, the guard 14 has a shape that does not protrude from the surface of the front panel 12 when it is installed in the guard accommodating portion 12d. The guard 14 is fixed to the guard accommodating portion 12d using a plurality of mounting screws 15 (see FIG. 5). In FIG. 5, only one mounting screw 15 is drawn as an example. In this case, the guard accommodating portion 12d has a plurality of through holes 12f through which the mounting screws 15 pass. On the other hand, although not shown, the guard 14 has a plurality of screw hole portions corresponding to each of the plurality of through holes 12f.

The sensor window 12e is a hole portion that exposes the sensing portion of the motion sensor 20, which will be described later, to the outside. In the present embodiment, the sensor window 12e is provided on the upper side of the front panel 12 and at a position closer to one side in the Y direction, which is the front width direction.

The operation panel 16 has a power button, various switching buttons, and the like for changing the operating state of the heating device 1. The operation panel 16 is installed on the upper surface portion 10c of the main body case 10.

FIG. 5 is an exploded perspective view showing the configuration of the heating device 1. FIG. 6 is a cross-sectional view of the heating device 1 corresponding to the VI-VI cross section in FIG. FIG. 7 is a perspective view of the heating device 1 in a state where only the main body case 10 is removed, as viewed diagonally from the rear.

The heating device 1 further includes a motion sensor 20, a circuit board 22, a fan 24, a motor 26, a motor support portion 30, a fan accommodating portion 40, a heating device 50, and a duct 60.

The motion sensor 20 functions as a detection unit that detects the movement of a heated object to be detected, such as a person who appears in front of the heating device 1. The heating device 1 can automatically start and stop the operation based on the detection of a person or the like by the motion sensor 20 without the person directly operating the operation panel 16.

The circuit board 22 mounts a control circuit or the like as a control unit that controls the operation of the heating device 1. The circuit board 22 is installed near the back surface of the operation panel 16. The operation panel 16, the motion sensor 20, the motor 26, and the heating device 50 are electrically connected to the circuit board 22.

The fan 24 is rotated by being driven by the motor 26, and takes in external air from the intake port 10b. The fan 24 is, for example, a sirocco fan having a large number of blades 24a arranged in a cylindrical shape and causing an air flow by centrifugal force. The central shaft 24b of the fan 24 is coaxially attached to the rotating shaft 26a of the motor 26.

The motor support portion 30 is a member that supports the motor 26. The motor support portion 30 is, for example, a flat plate member parallel to a plane formed by the Z direction, which is the height direction, and the Y direction, which is the front width direction. The motor support portion 30 has a through hole 31 that penetrates the rotation axis of the motor 26 at a position approximately at the center of the YZ plane. The motor 26 is attached to the motor support portion 30 by using a mounting screw 32 and a mounting nut 33 so that the rotating shaft 26a penetrates the through hole 31 from the front to the rear. In this case, the main body portion 26b of the motor 26 is located on the front side of the motor support portion 30. On the other hand, the fan 24 is located on the rear surface side of the motor support portion 30. Further, the motor support portion 30 has a plurality of air introduction holes 34 penetrating from the front surface side to the rear surface side radially with respect to the through holes 31. The hole region where the air introduction hole 34 is formed faces the inside of the cylinder of the fan 24. The main body 26b of the motor 26 may block a part of the hole region, but does not block the entire hole region. Therefore, when the fan 24 rotates, air is introduced from the main body 26b side to the fan 24 side through the air introduction hole 34. The introduced air is sucked into the cylinder of the fan 24 and then discharged to the outside of the cylinder of the fan 24. The motor support portion 30 may support the motion sensor 20 by using a screw or the like (not shown).

The fan accommodating portion 40 is a wall portion accommodating the fan 24 inside. In the present embodiment, the fan accommodating portion 40 is a combination of the first wall portion 35 integrated with the rear surface of the motor support portion 30 and the second wall portion 10e integrated with the inner surface of the main body case 10. Is. The fan accommodating portion 40 has a shape that surrounds the outer periphery of the fan 24 in a non-contact manner as a whole. That is, an accommodation space S0 surrounded by the fan accommodating portion 40, the rear surface of the motor support portion 30, and the inner surface of the main body case 10 is formed around the fan 24. Further, a part of the fan accommodating portion 40 is connected to the introduction port 63 of the duct 60 located below the fan accommodating portion 40. Therefore, the air discharged to the outside of the cylinder of the fan 24 is introduced into the accommodation space S0 and then guided to the introduction port 63. Here, in order to smooth the air flow in the accommodation space S0, the fan accommodating portion 40 is gradually spaced from the fan 24 in accordance with the rotation direction of the fan 24, that is, the air discharge direction by the fan 24. It may have a widening shape. Further, the fan accommodating portion 40 may have a spreading end 40a that spreads toward the introduction port 63.

Further, the fan accommodating portion 40 has an engaging portion 40b for engaging the introduction port 63 of the duct 60. For example, as shown in FIG. 7, the duct 60 has a flange portion 63a at the end of the introduction port 63. In this case, the engaging portion 40b may have a shape in which the flange portion 63a is slid along the X direction to engage with the flange portion 63a, and is sandwiched and held along the Z direction.

Further, as shown in FIG. 5, the motor support portion 30 is fixed to the main body case 10 by using a plurality of mounting screws 36. In FIG. 5, only one mounting screw 36 is drawn as an example. In this case, the motor support portion 30 has a plurality of through holes 30a through which the mounting screws 65 are passed. On the other hand, the main body case 10 has a plurality of screw hole portions 10f corresponding to each of the plurality of through holes 30a.

The heating device 50 heats the air sent from the fan accommodating unit 40. As the heating device 50, for example, a PTC heater is adopted. The heating device 50 is represented by a long plate-shaped block body in each of the drawings such as FIG. However, the heating device 50 is actually composed of, for example, a plurality of heat generating plates arranged in parallel so as to form a plurality of spaces penetrating in the thickness direction corresponding to the Z direction in the drawing. Therefore, the air sent from the fan accommodating portion 40 can penetrate the heating device 50 in the thickness direction. Further, a terminal 50a for connecting a lead wire 52 (see FIG. 7) is provided on one side surface of the heating device 50 in the longitudinal direction.

The duct 60 guides the air sent from the fan accommodating portion 40 to the outlet 14a. In the present embodiment, since the duct 60 is installed below the fan accommodating portion 40, the duct 60 has a shape of taking in air on the upper surface side and discharging air toward the front surface side as a whole. The duct 60 has an introduction port 63 for introducing the air taken in by the fan 24 from the fan accommodating portion 40, and an outlet 64 for leading out the air introduced from the introduction port 63 toward the outlet 14a.

The introduction port 63 is located on the upper surface side of the duct 60. The opening surface of the introduction port 63 is, for example, on an XY plane, is long in the Y direction, and is short in the X direction. On the other hand, the outlet 64 is located below the front side of the duct 60. The opening surface of the lead-out port 64 is, for example, on a YZ plane, is long in the Y direction, and is short in the Z direction. The opening shape of the outlet 64 substantially matches the opening shape of the outlet 14a. Further, the dimension of the introduction port 63 in the Y direction substantially matches the dimension of the outlet port 64 in the Y direction. The dimension of the introduction port 63 in the X direction is set to be larger than the dimension of the outlet port 64 in the Z direction. That is, the opening area of the introduction port 63 is preferably set larger than the opening area of the outlet port 64, and is preferably set to 1.2 times to 2.0 times the opening area of the outlet port 64, for example. As a result, the air sent from the fan accommodating portion 40 to the duct 60 is accelerated by the time it enters from the relatively wide introduction port 63 and exits from the relatively narrow outlet port 64, and is vigorously blown out from the outlet 14a. ..

The duct 60 has a front surface portion 60a, a rear surface portion 60b, a first side surface portion 60c, a second side surface portion 60d, and a bottom surface portion 60e so that the introduction port 63 and the outlet port 64 as defined above are formed. And have. The front surface portion 60a is a first wall portion having a lead-out port 64. The rear surface portion 60b is a second wall portion facing the front surface portion 60a in the X direction. The first side surface portion 60c and the second side surface portion 60d are side wall portions facing each other in the Y direction. The bottom surface portion 60e is a lower wall portion facing the introduction port 63. The bottom surface portion 60e has no opening, and the duct 60 forms a flow path having no outlet from the introduction port 63 to the outlet port 64. The opening surface of the introduction port 63 is a surface surrounded on all sides by the upper ends of the front surface portion 60a, the rear surface portion 60b, the first side surface portion 60c, and the second side surface portion 60d.

FIG. 8 is an enlarged cross-sectional view of the duct 60. The distribution space in the duct 60 generally includes the following four spaces, specifically, the first space S1, the second space S2, the third space S3, and the fourth space S4. The first space S1 to the fourth space S4 are each indicated by a two-dot chain line in the figure. Further, the lengths of the first space S1 to the fourth space S4 in the Y direction substantially match the lengths of the introduction port 63 or the outlet port 64 in the Y direction, respectively.

The first space S1 is a rectangular parallelepiped space having two first side surfaces P1 on which the opening surface of the introduction port 63 is projected and two second side surfaces P2 on which the opening surface of the outlet port 64 is projected. That is, the two first side surfaces P1 face each other in the Z direction. The two second side surfaces P2 face each other in the X direction. In this case, assuming that the inside of the duct 60 is viewed from the introduction port 63 along the Z direction, the first space S1 is visually recognized. Further, even if the inside of the duct 60 is viewed from the outlet 64 along the X direction, the first space S1 is visually recognized.

The second space S2 is a space having two third side surfaces P3 on which the opening surface of the introduction port 63 is projected and having no side surface on which the opening surface of the outlet port 64 is projected. That is, the second space S2 is a space facing the first space S1 in the Z direction. Further, the two third side surfaces P3 face each other in the Z direction. The second space S2 has two fourth side surfaces P4 as a YZ plane connecting the two third side surfaces P3. In this case, assuming that the inside of the duct 60 is viewed from the introduction port 63 along the Z direction, the second space S2 is visually recognized. However, even if the inside of the duct 60 is viewed from the outlet 64 along the X direction, the second space S2 is not visible because it does not have a side surface for projecting the opening surface of the outlet 64.

Further, a heating device 50 is installed in the second space S2. The duct 60 holds the heating device 50 so that the heating device 50 covers the cross section of the flow path in the second space S2. In the present embodiment, the air flow in the second space S2 goes from the upper side to the lower side along the Z direction. Further, the heating device 50 has a long plate shape and can penetrate air in the thickness direction. Therefore, the duct 60 holds the heating device 50 so that the thickness direction of the heating device 50 matches the Z direction. In this case, the air penetration surface of the heating device 50 is parallel to the opening surface of the introduction port 63 of the duct 60. Further, the first side surface portion 60c of the duct 60 has a through hole 60f that exposes the terminal 50a to the outside when the heating device 50 is installed.

The second space S2 is a rectangular parallelepiped space like the first space S1. However, in the present embodiment, the second space S2 is not limited to the rectangular parallelepiped space, and may have a different shape such that the fourth side surface P4 is inclined with respect to the YZ plane, for example.

The third space S3 is a space that supplements the distance G2 in the X direction from the first space S1 and the second space S2 to the outlet 14a. It is desirable that the third space S3 has a shape that easily guides air from the first space S1 or the second space S2 to the outlet 14a. Therefore, even if a part of the front surface portion 60a is an inclined wall 60g in which the opening area on the side in contact with the first space S1 and the second space S2 is wider than the opening area of the outlet 14a in the third space S3. good.

The fourth space S4 is a space included in the curved surface portion 60h formed on the rear surface portion 60b. The curved surface portion 60h is a wall portion that is convex from the inside to the outside of the duct 60 with the axis extending in the Y direction as the center of curvature. At least a part of the curved surface portion 60h faces the outlet 64.

The duct 60 has a convex portion (rib) 60r that protrudes inward (rearly) from the front surface portion 60a on the downstream side in the air flow direction from the position where the heating device 50 is installed. The convex portion 60r is provided at a position facing the curved surface portion 60h of the rear surface portion 60b. As shown in FIG. 6, it is desirable that the convex portion 60r is provided closer to the upstream side (upper end 60ht of the curved surface portion 60h) of the curved surface portion 60h in the air flow direction. More specifically, it is desirable that the height position of the convex portion 60r is between the upper end 60ht of the curved surface portion 60h and the intermediate portion 60hm in the Z direction in the Z direction. In the internal space of the duct 60, as shown by the arrow in FIG. 6, the downward air flow passing through the heating device 50 is bent toward the curved surface portion 60h by the convex portion 60r, and further along the shape of the curved surface portion 60h. It can be smoothly turned and moved forward. Although not shown, if an attempt is made to guide air from the inlet to the outlet with a duct that does not have a convex portion 60r and a curved surface portion 60h, the downward air flow directly hits the bottom portion 60e. , The pressure loss becomes large. By providing the duct 60 with the convex portion 60r and the curved surface portion 60h, air can flow smoothly and pressure loss can be reduced.

Further, the duct 60 has a structure in which the direction is changed from the vertical direction (downward) to the horizontal direction (forward) on the downstream side of the heating device 50 in the air flow direction. That is, the air flow after passing through the heating device 50 can be smoothly changed in direction by the convex portion 60r and the curved surface portion 60h, and can be blown out from the outlet 14a with the same momentum of the direction change.

Further, the duct 60 can be divided into a first divided body 61 and a second divided body 62. For example, the first division body 61 and the second division body 62 are divided along a YZ plane perpendicular to the X direction corresponding to the front-rear direction of the heating device 1. That is, the first divided body 61 and the second divided body 62 face each other in the X direction when they are combined with each other. The first divided body 61 may be a divided body on the side having the outlet 64. In this case, the second divided body 62 is a divided body on the side having the curved surface portion 60h. On the other hand, as shown in FIG. 5, the introduction port 63 is divided into the side of the first divided body 61 and the side of the second divided body 62.

The duct 60 may be composed of three or more divided bodies. For example, the duct 60 includes, in addition to the first division body 61 and the second division body 62, a third division body further divided along the YZ plane and sandwiched between the first division body 61 and the second division body 62. , Three divisions may be combined along the X direction.

Further, when the duct 60 can be divided into the first divided body 61 and the second divided body 62, the heating device 50 is sandwiched and held between the first divided body 61 and the second divided body 62. For example, the duct 60 has a plurality of protrusions 60i that support the side end portions of the heating device 50 on the inner surface of the front surface portion 60a facing the second space S2 and the inner surface of the rear surface portion 60b facing the second space S2. Have. The plurality of protrusions 60i are arranged so as to sandwich the heating device 50 in the Z direction and to sandwich the heating device 50 in the X direction.

As shown in FIG. 5, the first division body 61 and the second division body 62 are combined with each other by using a plurality of mounting screws 65. In FIG. 5, only one mounting screw 65 is drawn as an example. In this case, the first partition body 61 has a plurality of through holes 60j through which the mounting screw 65 is passed. On the other hand, the second divided body 62 has a plurality of screw hole portions 60k corresponding to each of the plurality of through holes 60j.

Further, the duct 60 has a protrusion 60n having a through hole 60m through which the mounting screw 66 is passed through the bottom surface portion 60e. On the other hand, the main body case 10 has a screw hole 10k for fastening the mounting screw 66 at a position corresponding to the through hole 60 m on the inner surface side. The duct 60 is fixed to the main body case 10 by engaging the flange portion 63a with the engaging portion 40b of the fan accommodating portion 40 and using the mounting screws 66.

The duct 60 may have, for example, a fuse accommodating portion 60p on the front surface portion 60a, which accommodates a fuse installed when the heating device 50 is used.

Here, the motor support portion 30 is above the duct 60 in the vertical direction. Further, the motor support portion 30 is supported by the main body case 10 on the rear surface side of the housing 2. That is, the motor support portion 30 is supported by the housing 2 on the side to which the fan accommodating portion 40 is connected. Therefore, the position of the center of gravity of the heating device 1 as a whole tends to be located above and behind the heating device 1. Therefore, the base 18 that supports the housing 2 has a shape in which the side that supports the motor support portion 30 projects horizontally from the housing 2 rather than the opposite side. Here, the side that supports the motor support portion 30 in the horizontal direction means the rear side in the front-rear direction corresponding to the X direction. On the other hand, the side opposite to the side that supports the motor support portion 30 in the horizontal direction means the front side in the front-rear direction. Specifically, referring to FIG. 6, the front end portion 18a of the base 18 is approximately aligned with the surface position of the front panel 12. That is, the front end portion 18a does not protrude from the front panel 12 which is a part of the housing 2. On the other hand, the rear end portion 18b of the base 18 projects outward by a distance L from the surface of the main body case 10 which is a part of the housing 2.

Further, the circuit board 22 is above the motor support portion 30 in the Z direction. On the other hand, the heating device 50 is below the motor support portion 30 in the Z direction. The circuit board 22 and the heating device 50 are electrically connected by a plurality of lead wires 52. Here, as shown in FIG. 7, the motor support portion 30 has a hook portion 37 for arranging the lead wire 52 at the side end portion 30b. The hook portion 37 includes, for example, a first hook 37a and a second hook 37b, both of which have a shape obtained by deforming a flat plate into an L shape. The first hook 37a is erected in the Y direction from the front end of the side end portion 30b, and the tip end portion faces rearward in parallel with the side end portion 30b. On the other hand, the second hook 37b is erected in the Y direction from the rear end of the side end portion 30b at a distance in the Z direction from the first hook 37a, and the tip portion is parallel to the side end portion 30b and is forward. Facing to the side. When the operator arranges the lead wire 52 in the hook portion 37, the operator temporarily inserts the lead wire 52 between the first hook 37a and the second hook 37b with the lead wire 52 laid down along the X direction, and then inserts the lead wire 52 between the first hook 37a and the second hook 37b. , The posture of the lead wire 52 may be changed along the Z direction. With such a line, the movement of the lead wire 52 to the front side is restricted by the first hook 37a, and the movement to the rear side is restricted by the second hook 37b. On the other hand, the movement of the lead wire 52 in the Y direction is restricted by both the first hook 37a and the second hook 37b.

Further, the main body case 10 which is a part of the housing 2 has an intake port 10b for sucking in external air. The position where the intake port 10b is formed and the distribution path of the air sucked from the intake port 10b in the heating device 1 are defined as follows, for example.

FIG. 9 is a cross-sectional view of the heating device 1 corresponding to the IX-IX cross section in FIG. In FIG. 9, the distribution path from the intake port 10b to the fan 24 of the air sucked in as the fan 24 rotates is indicated by an arrow. The intake port 10b is formed at two positions in the main body case 10 so as to penetrate from the rear side to the front side in the front-rear direction.

First, as shown in FIG. 4, each of the intake ports 10b has an elongated planar shape in which a plurality of through holes are lined up along the Z direction. Of the two intake ports 10b, one intake port 10b is provided in the vicinity of the first side surface portion 10g, which is one side surface portion of the main body case 10. The other intake port 10b is provided in the vicinity of the second side surface portion 10h, which is the other side surface portion of the main body case 10. The height position where the intake port 10b is provided substantially matches the height position of the fan 24 in the Z direction. Although not shown, a filter for suppressing the entry of dust or the like into the heating device 1 may be installed on the back surface of the intake port 10b, although not shown.

Here, as shown in FIG. 9, the heating device 1 includes a first distribution path PA1 that allows the air sucked from the intake port 10b by the fan 24 to pass to the outside of the fan accommodating portion 40. In the Y direction corresponding to the front width direction of the heating device 1, between one side end portion 30b of the motor support portion 30 and the first side surface portion 10g of the main body case 10 facing the side end portion 30b. There is an interval G3. The same applies between the other side end portion 30b of the motor support portion 30 and the second side surface portion 10h of the main body case 10 facing the side end portion 30b. Therefore, the first distribution path PA1 passes through the space of the interval G3 from the rear surface side of the motor support portion 30 toward the front surface side of the motor support portion 30 along the X direction, and finally the front panel. It hits 12 g on the back surface of 12.

In this embodiment, it is assumed that a gap G3 exists in advance between the side end portion 30b of the motor support portion 30 and the side surface portion of the main body case 10. However, due to the dimensions of the motor support portion 30, there may be a case where there is almost no gap between the side end portion 30b of the motor support portion 30 and the side surface portion of the main body case 10. In this case, by forming through holes in the motor support portion 30 in advance on the front surface side and the rear surface side, it is possible to provide the first distribution path PA1 passing through the through holes.

Further, as described above, the motor support portion 30 has a plurality of air introduction holes 34 penetrating from the front surface side to the rear surface side. When the fan 24 rotates, the air on the front surface side of the motor support portion 30 passes through the plurality of air introduction holes 34 and is sucked into the rear surface side of the motor support portion 30, that is, the inside of the fan accommodating portion 40. That is, the heating device 1 includes a second distribution path PA2 that circulates the air that has passed through the first distribution path PA1 on the side surface side of the motor 26 and inside the fan accommodating portion 40. The air flowing along the first distribution channel PA1 changes the traveling direction on the back surface 12 g of the front panel 12. Then, the air whose traveling direction is changed continues to travel along the second distribution channel PA2 by being sucked by the fan 24. The air distribution route from the first distribution route PA1 to the second distribution route PA2 is shown as the third distribution route PA3 in FIG.

The traveling direction of the air in the first distribution path PA1 and the traveling direction of the air in the second distribution path PA2 are parallel to the rotation axis 26a of the motor 26, that is, along the X direction corresponding to the front-rear direction. It becomes the direction. However, the traveling direction of air in the first distribution path PA1 and the traveling direction of air in the second distribution path PA2 are opposite to each other as described above.

As described above, the heating device 1 according to the present embodiment is installed inside the housing 2, and has a fan 24 that takes in outside air, a heating device 50 that heats the air taken in by the fan 24, and a heating device. It is provided with a blowout portion 12c that blows out the air heated by 50 to the outside. The heating device 1 includes a duct 60 having an introduction port 63 for introducing the air taken in by the fan 24 and an outlet port 64 for leading out the air introduced from the introduction port 63 toward the blowout portion 12c. The duct 60 includes a rectangular parallelepiped first space S1 having two first side surfaces P1 on which the opening surface of the introduction port 63 is projected and two second side surfaces P2 on which the opening surface of the outlet port 64 is projected. ..

According to such a heating device 1, since the distribution space in the duct 60 includes at least the first space S1, the volume of the duct 60 is larger than the volume of the conventional fan case. The conventional fan case has a curved cross section that minimizes the volume of the distribution space. Since the distribution space of the fan case having such a shape cannot include the rectangular parallelepiped first space S1 whose size is defined by the first side surface P1 and the second side surface P2, the duct including the first space S1. The distribution space in 60 has a larger volume. Therefore, the duct 60 can circulate more air sent from the fan 24 than before. Further, for example, it is assumed that the size of the fan 24 is made larger than before in order to increase the air volume of the warm air. Even in this case, by using the duct 60 having a large volume of the distribution space, the flow of the circulating air is less likely to be obstructed, so that the air volume of the air can be suitably increased as compared with the conventional case. Therefore, according to the present embodiment, it is possible to provide the heating device 1 which is advantageous for increasing the air volume of the warm air.

Further, in the heating device 1 according to the present embodiment, the duct 60 has two third side surfaces P3 on which the opening surface of the introduction port 63 is projected, and the side surface on which the opening surface of the outlet port 64 is projected. The heating device 50 may be installed in the second space S2, including the second space S2 which does not have.

For example, with respect to the plurality of fins 14b provided on the guard 14, the distance G1 between the fins 14b is set to be smaller than the width of the fingers of an adult hand. Therefore, basically, it is difficult for an adult to directly insert a finger into the outlet 14a, which can be hot. However, for example, in the case of an infant, depending on the size of the interval G1, it may be possible to insert the finger of the hand toward the outlet 14a. At this time, assuming that the heating device 50 is installed in the vicinity of the outlet 64 of the duct 60 in contact with the outlet 14a, for example, when an infant accidentally inserts a finger of the hand toward the outlet 14a, the heating device 50 is heated. It is also possible to touch the device 50.

On the other hand, according to the heating device 1, the heating device 50 is installed in the second space S2, that is, it is not installed in the first space S1 on the side close to the outlet 64. That is, since the heating device 50 is installed at a position far from the outlet 64, even if the infant inserts the finger of the hand toward the outlet 14a, the heating device 50 will be touched in advance. It can be deterred.

On the other hand, in the conventional heating device, even if the heating device is installed near the outlet, by installing a filter between the outlet and the heating device, the heating device can be directly touched from the outlet side. Some have adopted a configuration that prevents them from doing so. On the other hand, in the heating device 1, since the position of the heating device 50 itself is kept away from the outlet 14a, it is not necessary to install a filter as conventionally used, which may be advantageous in terms of reducing the number of components. .. In addition, this can contribute to an increase in air volume by not installing components that can cause pressure loss in the distribution space of the duct 60 as much as possible.

Further, in the heating device 1 according to the present embodiment, the duct 60 can be divided into the first divided body 61 and the second divided body 62, and the heating device 50 is divided into the first divided body 61 and the second divided body 62. It may be sandwiched between 62 and held.

According to such a heating device 1, it is not necessary to use a fastening member such as a screw specialized for holding the heating device 50, which may be advantageous in terms of reducing the number of components. Further, when assembling the heating device 1, the heating device 50 can be held at the same time as the step of combining the first divided body 61 and the second divided body 62, so that the assembling process of the heating device 1 can be simplified. It can be advantageous.

Further, in the heating device 1 according to the present embodiment, the duct 60 faces the second wall portion facing the first wall portion where the outlet port 64 is formed, and at least a part of the duct 60 faces the outlet port 64. It may have a curved surface portion 60h that is convex from the inside to the outside of the 60. Here, the first wall portion corresponds to, for example, the front surface portion 60a of the duct 60. In this case, the second wall portion corresponds to the rear surface portion 60b.

According to such a heating device 1, even if the circulation space of the duct 60 includes the rectangular parallelepiped first space S1, the air flow is shown by the curved surface portion 60h as shown by the arrow in FIG. It is possible to smoothly proceed from the introduction port 63 to the outlet port 64 along the shape.

Further, the heating device 1 according to the present embodiment is connected to the motor 26 that rotates the fan 24, the motor support portion 30 that supports the motor 26 on the side connecting the fan 24, and the motor support portion 30. A fan accommodating portion 40 accommodating the fan 24 may be provided. The heating device 1 accommodates the air sucked by the fan 24 on the side surface side of the motor 26 and the fan accommodating the first distribution path PA1 for passing the air sucked by the fan 24 to the outside of the fan accommodating portion 40 and the air passing through the first distribution path PA1. A second distribution channel PA2 to be distributed inside the unit 40 may be provided. The traveling direction of air in the first distribution path PA1 and the traveling direction of air in the second distribution path PA2 may be parallel to the rotation axis of the motor 26 and may be opposite to each other.

According to such a heating device, the air taken into the inside of the heating device 1 passes outside the fan accommodating portion 40 and then turns, passes through the side surface side of the motor 26, and passes inside the fan accommodating portion 40. Head to. That is, the air taken into the inside of the heating device 1 comes into contact with the side surface of the motor 26 before being introduced into the inside of the fan accommodating portion 40, which is advantageous for dissipating the heat of the motor 26. .. Further, for example, it is assumed that the rating of the motor 26 is made higher than before in order to increase the air volume of the warm air. Even in this case, since it is advantageous for heat dissipation of the motor 26, it becomes easy to cope with an increase in the rating of the motor, so that the air volume of the air can be suitably increased as compared with the conventional case.

Further, in the heating device 1 according to the present embodiment, the housing 2 may have an intake port 10b formed at a position along the first distribution path PA1.

According to such a heating device 1, air can be introduced into the first distribution channel PA1 more smoothly.

Further, in the heating device 1 according to the present embodiment, the motor support portion 30 may have a hook portion 37 at the side end portion 30b.

According to such a heating device 1, the lead wire 52 is easily arranged when the heating device 1 is assembled, which may be advantageous in terms of simplifying the assembly process of the heating device 1. Further, as shown in FIG. 9, the side end portion 30b of the motor support portion 30 is in contact with a part of the first distribution path PA1. Therefore, when the lead wire 52 has heat, it may be advantageous in terms of heat dissipation of the lead wire 52.

Further, in the heating device 1 according to the present embodiment, the motor support portion 30 may be supported by the housing 2 above the duct 60 in the vertical direction and on the side to which the fan accommodating portion 40 is connected. The housing 2 may include a base 18 whose side supporting the motor support portion 30 projects horizontally from the housing 2 rather than the opposite side.

According to such a heating device 1, the base 18 can stably support the housing 2 even when the center of gravity is located above and behind the heating device 1.

Next, an embodiment different from the above-described embodiment will be described with reference to the drawings. For elements having substantially the same function and configuration as those of the above-described embodiment, duplicate explanations are omitted by assigning the same reference numerals, and elements not directly related to the embodiment are described. , Illustrated.

FIG. 10 is a perspective view showing the appearance of the heating device 1A according to the embodiment. FIG. 11 is a side view of the heating device 1A. FIG. 12 is a front view of the heating device 1A. FIG. 13 is a rear view of the heating device 1A. FIG. 14 is a plan view of the heating device 1A.

Further, FIG. 15 is a cross-sectional view of the heating device 1A corresponding to the XV-XV cross section in FIG. FIG. 16 is an exploded perspective view of the intake port 10b in the main body case 10 as viewed diagonally from the front. FIG. 17 is a perspective view of the outlet 14a of the front panel 12 as viewed diagonally from the rear.

As shown in FIGS. 10 to 14, the heating device 1A includes a pedestal portion (fixed portion) 70, a housing (swivel portion) 2, and a swing mechanism 71 (see FIG. 15). The pedestal portion 70 is placed on the floor surface, which is the installation surface, and supports the housing 2. The pedestal portion 70 is formed in a circular shape in a plan view. The housing 2 has a bulging portion 72 that bulges in the horizontal direction (front-back direction) from the lower part of the main body case 10 so as to correspond to the circular pedestal portion 70. The housing 2 is mounted on the upper part of the pedestal portion 70 so as to be swingable.

As shown in FIG. 15, the swing mechanism 71 includes a swing motor 73 and a support mechanism 74. The swing motor 73 is fixed to the main body case 10, and the swing motor 73 and the pedestal portion 70 are connected via a link mechanism 75. The support mechanism 74 is arranged between the pedestal portion 70 and the main body case 10. The support mechanism 74 is formed and supported by an annular rail 76 provided on the upper part of the pedestal portion 70, a support (sphere) 77 rotatably arranged on the rail 76, and a lower part of the main body case 10. It has a holding portion 78 for holding the body 77. The support 77 is arranged between the pedestal portion 70 and the bulging portion 72 and between the pedestal portion 70 and the main body case 10 to support the load of the housing 2.

By such a swing mechanism 71, the housing 2 swings in the horizontal direction (left-right direction) with respect to the pedestal portion 70 within an angle range of the set swing angle θ1 (for example, 90 °) (see FIG. 14). .. Further, by arranging the swing motor 73 in the lower part of the housing 2 (main body case 10), the center of gravity moves toward the lower part of the heating device 1A, and the stability of mounting the heating device 1A on the floor surface is improved. is doing.

The circuit board 22 has a control unit that controls the swing operation by the swing mechanism 71 and the operating state of the heating operation by the motor 26 and the heating device 50. When the swing mechanism 71 turns the housing 2 in the horizontal direction (left-right direction) with respect to the pedestal portion 70, the control unit automatically stops and automatically starts the heating operation based on the motion sensor 20. No control.

The intake port 10b shown in FIG. 16 has an enlarged opening area as compared with the intake port 10b in the embodiment shown in FIG. As shown in FIG. 16, a filter 80 for suppressing the entry of dust or the like into the inside of the heating device 1A is installed on the back surface of the intake port 10b. The filter 80 is a resin frame 81 in which a mesh filter 82 is insert-molded, and separates dust and the like from air.

As shown in FIG. 17, the outlet 14a is provided with a louver 83 that is rotatable in the vertical direction. The louver 83 is manually rotated upward by a set rotation angle θ2 (for example, 20 ° to 25 °) from the horizontal position shown in FIG. A spring (wire spring) 86 is attached between the shaft portions 84 at both ends of the louver 83 and the shaft support portion 85 on the front panel 12 side, and the louver 83 is held at a desired rotation angle by the spring 86. Ru. By swinging the housing 2 in the left-right direction with respect to the pedestal portion 70 in a state where the louver 83 is rotated upward from the horizontal position, warm air can be diffused in the up-down direction as well, and heating can be performed. The efficiency of heating by the device 1A can be increased.

As described above, the heating device 1A according to the embodiment is mounted on the installation surface (floor surface), and the pedestal portion 70 that supports the housing 2 and the housing 2 are placed in the horizontal direction with respect to the pedestal portion 70 ( It is provided with a swing mechanism 71 that swivels in the left-right direction).

According to such a heating device 1A, the warm air blown from the outlet 14a can be diffused in the horizontal direction (left-right direction), and a wide range in front of the heating device 1A can be heated.

Further, in the heating device 1A according to the embodiment, the pedestal portion 70 is formed in a circular shape in a plan view, and the housing 2 corresponds to the circular pedestal portion 70 in the horizontal direction from the lower part of the housing 2. It may have a bulging portion that bulges out. A support 77 that supports the load of the housing 2 may be arranged between the pedestal portion 70 and the bulging portion 72.

According to the heating device 1A, the housing 2 that is swiveled in the horizontal direction (left-right direction) with respect to the pedestal portion 70 can be stably supported.

Further, the heating device 1A according to the embodiment may include a control unit (circuit board 22) and a detection unit (human sensor 20) for detecting the movement of a heated object to be detected. The control unit (circuit board 22) automatically stops and automatically starts the heating operation based on the detection unit (presence sensor 20) when the swing mechanism 71 turns the housing 2 in the horizontal direction with respect to the pedestal unit 70. May be controlled so as not to perform.

According to the heating device 1A, when the swing mechanism 71 swivels the housing 2 in the horizontal direction with respect to the pedestal portion 70, an object warmed by the warm air blown from the outlet 14a is an object to be detected. It is possible to prevent misidentification detection that is detected as.

Although the preferred embodiment has been described above, the embodiment is not limited to these, and various modifications and changes can be made within the scope of the gist thereof.

1,1A Heating device 2 Housing 10b Intake port 12c Blow-out part 18 Base 20 Motion sensor (detection part)
22 Circuit board (control unit)
24 Fan 26 Motor 30 Motor support part 30b Side end part 37 Hook part 40 Fan accommodating part 50 Heating device 60 Duct 60h Curved surface part 61 1st split body 62 2nd split body 63 Introductory port 64 Outlet port 70 Pedestal part 71 Swing mechanism 72 Swelling part 77 Support P1 1st side surface P2 2nd side surface P3 3rd side surface PA1 1st distribution route PA2 2nd distribution route S1 1st space S2 2nd space

Claims (9)

With the housing
A fan installed inside the housing that takes in outside air,
A heating device that heats the air taken in by the fan,
A blowout part that blows out the air heated by the heating device to the outside,
It is provided with a duct having an introduction port for introducing the air taken in by the fan and an outlet for drawing out the air introduced from the introduction port toward the blowout portion.
The duct includes a rectangular parallelepiped first space having two first side surfaces on which the opening surface of the inlet is projected and two second sides on which the opening surface of the outlet is projected.
The duct has a curved surface portion that faces the first wall portion in which the outlet is formed, at least a part of which faces the outlet, and is convex from the inside to the outside of the duct. Has a heating device. The duct includes a second space having two third sides on which the opening surface of the inlet is projected and having no side surface on which the opening surface of the outlet is projected.
The heating device according to claim 1, wherein the heating device is installed in the second space. The duct can be divided into a first division body and a second division body, and the duct can be divided into a first division body and a second division body.
The heating device according to claim 1 or 2, wherein the heating device is sandwiched between the first divided body and the second divided body and held. With the housing
A fan installed inside the housing that takes in outside air,
A heating device that heats the air taken in by the fan,
A blowout part that blows out the air heated by the heating device to the outside,
It is provided with a duct having an introduction port for introducing the air taken in by the fan and an outlet for drawing out the air introduced from the introduction port toward the blowout portion.
The duct includes a rectangular parallelepiped first space having two first side surfaces on which the opening surface of the inlet is projected and two second sides on which the opening surface of the outlet is projected.
The motor that rotates the fan and
A motor support portion that supports the motor on the side to which the fan is connected, and
A fan accommodating portion connected to the motor support portion and accommodating the fan,
A first distribution path for passing the air sucked by the fan to the outside of the fan accommodating portion,
A second distribution path for circulating the air that has passed through the first distribution path to the side surface side of the motor and the inside of the fan accommodating portion is provided.
A heating device in which the traveling direction of air in the first distribution path and the traveling direction of air in the second distribution path are parallel to the rotation axis of the motor and opposite to each other. The heating device according to claim 4 , wherein the housing has an intake port formed at a position along the first distribution channel. The heating device according to claim 4 or 5 , wherein the motor support portion has a hook portion at a side end portion. The motor support portion is supported by the housing above the duct in the vertical direction and on the side to which the fan accommodating portion is connected.
The heating device according to any one of claims 4 to 6 , wherein the housing includes a base in which the side supporting the motor support portion projects horizontally from the housing rather than the opposite side. With the housing
A fan installed inside the housing that takes in outside air,
A heating device that heats the air taken in by the fan,
A blowout part that blows out the air heated by the heating device to the outside,
It is provided with a duct having an introduction port for introducing the air taken in by the fan and an outlet for drawing out the air introduced from the introduction port toward the blowout portion.
The duct includes a rectangular parallelepiped first space having two first side surfaces on which the opening surface of the inlet is projected and two second sides on which the opening surface of the outlet is projected.
A pedestal that is placed on the installation surface and supports the housing,
A swing mechanism for rotating the housing in the horizontal direction with respect to the pedestal portion is provided.
The pedestal portion is formed in a circular shape in a plan view.
The housing has a bulging portion that bulges horizontally from the lower part of the housing so as to correspond to the circular pedestal portion.
A heating device in which a support for supporting the load of the housing is arranged between the pedestal portion and the bulging portion. It is equipped with a control unit and a detection unit that detects the movement of a heated object to be detected.
The control unit controls the swing mechanism so as not to automatically stop and automatically start the heating operation based on the detection unit when the housing is swiveled in the horizontal direction with respect to the pedestal unit. Item 8. The heating device according to item 8.

Images