KR20050027014A - Rotary damper - Google Patents

Abstract

A rotary damper is provided to reduce noise by forming an air standing part in the resisting part and guiding and staying air from the housing into the air standing part with a guide unit. A rotary damper is composed of a case made of synthetic resin, silicone oil as viscous fluid stored in the case, a rotor(31) having a resisting part(36) formed in a shaft part partially protruded out of the case and moved in the silicone oil of the case, a penetration hole penetrated by the shaft part of the rotor, a synthetic resin cap closing the opening part of the case, an O-ring preventing leak of silicone oil between the cap and the shaft part of the rotor, and a synthetic resin driven gear mounted to the shaft part protruded from the cap. A thin plate(37) is formed in the resisting part, and a guide wall(38) is formed to guide air from the housing into the inner periphery of the thin plate in turning the rotor.

Description

Rotary Damper {ROTARY DAMPER}

The present invention relates to, for example, a rotary damper for braking the rotation of a driven gear engaged with a gear or rack.

The rotary damper may include a rotor having a housing, a viscous fluid accommodated in the housing, a shaft accommodated in the housing, and a resistance part moving in the viscous fluid in the housing, the shaft part of the housing protruding from the housing; It consists of a sealing member that prevents the viscous fluid from leaking between the housing and the housing. In addition, a driven gear is attached to the shaft portion protruding from the housing.

(Patent Document 1) Japanese Patent Application Laid-Open No. 4-34015

Conventional rotary dampers have a platelet shape that is substantially plate-shaped so that air entrained in the housing during assembly is not located between the resistance portion of the rotor, which is the torque generating portion, and the bottom or ceiling surface of the housing. I am doing it.

However, since the rotor rotates in both directions, noise is generated when air entrained in the housing moves over the resistance portion and moves to the opposite side of the resistance portion.

The noise generated when the air mixed in the housing crosses the resistance portion is compressed by the air mixed in the housing as it rises through the resistance portion, and then the popping sound due to the rapid opening when passing over the resistance portion. I think).

In addition, such a joint easily occurs as the viscosity of the viscous fluid increases, and also occurs as the gap between the rotor and the housing decreases.

The present invention provides a rotary damper capable of preventing the occurrence of noise caused by the air mixed in the housing even when the rotor rotates in both directions by preventing the air mixed in the housing from passing through the resistance portion.

The present invention is as follows.

(1) a rotor having a housing, a viscous fluid accommodated in the housing, a shaft part accommodated in the housing and protruding from the housing, the resistance part moving in the viscous fluid in the housing, the shaft part and the housing; A rotary damper comprising a sealing member that prevents the viscous fluid from leaking between an air rectifier comprising a concave portion or a hole in the resistance portion, and the air in the housing is formed by the rotation of the rotor. Characterized in that the guide means for guiding to move to the rectifying unit.

(2) The rotation damper (1) is characterized in that the air rectifying portion is formed on the inner circumferential side of the resistor portion, and the guide means is a guide wall vortexed from the outer circumferential end of the resistor portion to the inner circumferential side.

(3) In the rotary damper (1) or (2) above, an air holding part is formed on at least one of an inner circumferential side of the bottom surface of the housing and an inner circumferential side of the ceiling surface of the housing.

(4) The damper (1) is characterized in that the air rectifying portion is formed on the outer circumferential side of the resistor portion, and the guide means is a concave groove passing from the inner circumferential side of the resistor portion to the outer circumferential side.

(5) In the rotary damper (4), an annular protruding wall is formed in the resistance portion outside the concave groove.

(6) In the rotary damper (4) or (5) above, an air holding part is formed on at least one of an outer circumferential side of the bottom surface of the housing and an outer circumferential side of the ceiling surface of the housing.

According to the present invention, since the air rectifying portion formed of the concave portion or the hole is formed in the resistance portion, and the guide means for guiding the air in the housing to move to the air rectifying portion is formed by the rotation of the rotor, it is incorporated in the housing during assembly. Collected air can be collected and stayed in the air rectifier.

Therefore, even if the rotor rotates in both directions, the air mixed in the housing does not ride over the resistance portion, thereby preventing the occurrence of noise caused by the air mixed in the housing.

Since the air rectifying portion is formed on the inner circumferential side of the resistor portion, and the guide means is a guide wall facing the inner circumferential side in a vortex form at the outer circumferential end of the resistor portion, the air mixed in the housing is directed to the air rectifying portion by the guide wall. It is possible to keep the air entrained in the portion where no negative pressure occurs.

Further, since the air holding part is formed on at least one of the inner circumferential side of the bottom surface of the housing and the inner circumferential side of the ceiling surface of the housing, the air mixed in the housing can be held in the air holding part so as to stay in the air holding part.

In addition, since the air rectifying portion is formed on the outer circumferential side of the resistor portion, and the guide means is a concave groove that passes from the inner circumferential side of the resistor portion to the outer circumferential side, the air entrained in the housing is directed to the air rectifying portion through the concave groove, so as to remain in the air rectifying portion. can do.

And since the annular protrusion wall is formed in the resistance part of the outer side of the concave groove, the air mixed in the housing can be kept in the air rectifying part so as not to flow between the inner circumferential surface of the housing which is the braking torque generating part and the outer circumferential surface of the resistance part. .

In addition, since the air holding part is formed on at least one of the outer circumferential side of the bottom surface of the housing and the outer circumferential side of the ceiling surface of the housing, the air mixed in the housing can be held in the air holding part so as to stay in the air holding part.

Embodiment of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described based on drawing.

(First embodiment)

1 is a cross-sectional view of a rotary damper according to a first embodiment of the present invention, FIG. 2 is an enlarged cross-sectional view of the rotor shown in FIG. 1, FIG. 3 is a plan view of the rotor shown in FIG. Bottom view.

In Fig. 1, reference numeral D denotes a rotary damper, a case 11 made of synthetic resin, a silicone oil 21 as a viscous fluid contained in the case 11, and a case 11 contained therein, and a case 11 And a rotor 31 made of a synthetic resin having a resistance portion 36 which moves in the silicone oil 21 in the case 11 on the shaft portion 32 which protrudes outwardly from A through hole 52 through which the shaft portion 32 of the shaft penetrates is formed, and a cap 51 made of synthetic resin that closes the opening of the case 11, and the shaft portion 32 of the cap 51 and the rotor 31. 0-ring 61 as a sealing member to prevent the silicone oil 21 from leaking out between the? And the driven gear made of synthetic resin attached to the shaft portion 32 of the rotor 31 protruding from the cap 51. It consists of 71.

The housing is composed of a case 11 and a cap 51.

The case 11 has a case body 12 having a cylindrical wall portion 14 formed along the outer circumference of the bottom portion 13 having a circular planar shape, and a cylindrical paper sheet formed at the center of the bottom surface of the bottom portion 13. The branch part 16 and the outer peripheral surface of the case main body 12 are formed in the radial direction at 180 degree intervals, and are comprised by the attachment flange 17 provided with the attachment hole 18. As shown in FIG.

And the annular air holding groove as an air holding part which keeps air A not to flow out in the inner peripheral side of the bottom surface of the bottom part 13 (part corresponding to the inner peripheral side part of the thin plate part 37 mentioned later). 13a is formed.

Further, on the upper side of the cylindrical wall portion 14, a thin projecting wall portion 14a having a surface extending the inner circumferential surface of the cylindrical wall portion 14 as an inner circumferential surface is formed.

Reference numeral 15 denotes an accommodating portion formed in the case main body 12 and corresponds to a lower portion of the protruding wall portion 14a as a portion for accommodating the silicone oil 21.

The rotor 31 is a cylindrical shaft portion 32 and a plate-shaped resistance portion 36 extending radially from the shaft portion 32 at intervals of 180 degrees, and having a planar shape forming a circle I-cut. Consists of. The part cut out by the cut of this resistance part 36 is corresponded to the air chamber which collects air A mixed in the case 11 at the time of an assembly at the initial stage.

The shaft portion 32 is provided with a cylindrical recess 33 on which the shaft support portion 16 of the case 11 is rotatably fitted on its bottom surface, and protrudes from the cap 51. An I-cut stepped portion 34 cut in I is formed, and fitting grooves 35 in the horizontal direction are formed in the flat portion (vertical surface) cut in I.

2 and 3, the thin plate portion 37 is formed symmetrically on the upper side of the resistor portion 36 toward the inner circumferential side in a vortex (left turn) at the outer circumferential end thereof. ) Is an outer wall of the guide wall 38 as a guide wall 38 as a guide means for guiding the air A in the case 11 to move to the inner circumferential side (center) of the thin plate portion 37 by the rotation of the rotor 31. 2 and 4, a thin plate portion 37 is formed symmetrically from the outer circumferential end toward the inner circumferential side in a vortex shape (left turn), and the outer wall of the thin plate portion 37 is a rotor ( The guide wall 38 serves as a guide means for guiding the air A in the case 11 to move to the inner circumferential side (center) of the thin plate portion 37 by the rotation of 31. In addition, two thin plate portions 37 which are symmetrical are connected to each other.

And the thin plate part 37 functions as an air rectification part which consists of recesses as a whole, but the inner peripheral part part functions as an air rectification part especially.

The cap 51 has a through hole 52 through which the shaft portion 32 of the rotor 31 penetrates at the center thereof, and the inner circumferential surface of the through hole 52 has a cylindrical shape from its middle portion to the lower end thereof. By further cutting, a stepped portion 53 is formed in which the 0 ring 61 is accommodated, and air is formed on the inner circumferential side of the lower side (ceiling surface) (a portion slightly outside the inner circumferential side portion of the thin plate portion 37). An annular air retaining groove 54 is formed as an air retaining portion for keeping (A) from flowing out, and a fitting in which the protruding wall portion 14a of the case body 12 is fitted to the outer periphery of the lower side. Concave grooves 55 are formed.

In addition, an I-cut attachment hole 72 is formed in the center of the driven gear 71, and a fitting groove formed in the shaft portion 32 of the rotor 31 in the planar portion of the attachment hole 72 is formed. The fitting protrusion 73 to be fitted to the 35 is formed.

Next, an example of assembly of the rotary damper D is demonstrated.

First, the 0 ring 61 is inserted into the shaft portion 32 of the rotor 31, and the silicone oil 21 is applied to the recess 33 and the resistance 36, and then the recess 33 A part of the shaft portion 32 and the resistance portion 36 are accommodated into the accommodating portion 15 while fitting the shaft supporting portion 16 of the case 11 into the c).

Then, after the appropriate amount of the silicone oil 21 is injected into the receiving portion 15, the fitting recess groove 55 while penetrating the shaft portion 32 of the rotor 31 into the through hole 52 of the cap 51. By fitting the protruding wall portion 14a into the inside, the opening of the case 11 is closed by the cap 51.

When the opening of the case 11 is closed with the cap 51 in this manner, most of the air A in the protruding wall portion 14a is discharged out of the case 11, and the protruding wall portion 14a and the cap 51 come into close contact with each other. At the same time, the 0 ring 61 is accommodated in the step portion 53, and the 0 ring 61 prevents the silicone oil 21 from leaking between the shaft portion 32 and the cap 51.

And between the protruding wall part 14a and the cap 51, it welds and seals, for example by the high frequency weld bonding method.

Then, when the shaft portion 32 protruding from the cap 51 is pushed into the mounting hole 72 of the driven gear 71, the fitting protrusion 73 is fitted into the fitting groove 35 so that the rotary damper is fitted. Assembly of (D) is complete | finished.

Subsequently, the operation will be described.

First, as indicated by the solid arrows in FIG. 3, when the rotor 31 rotates counterclockwise, the resistance portion 36 in the silicone oil 21 rotates counterclockwise, and at this time, the resistance The viscous resistance and shear resistance of the silicone oil 21 act on the part 36 to brake the rotation of the rotor 31.

Therefore, the driven gear 71 attached to the rotor 31 brakes the rotation or movement of the gear, rack, etc. to which the driven gear 71 is engaged to make the rotation or movement slow.

As the negative pressure portion is generated downstream of the resistance portion 36 when the rotor 31 rotates counterclockwise in this way, the air A mixed into the case 11 at the time of assembly is indicated by a solid line. It follows the negative pressure part and moves.

By the way, when the rotor 31 rotates in the counterclockwise direction, since the thin plate portion 37 and the guide wall 38 are formed below the resistance portion 36 as shown in FIG. When the electron 31 rotates clockwise as shown by the dotted arrow in FIG. 3, the air indicated by the dotted line following the negative pressure portion generated downstream of the resistance part 36 is moved to the thin plate portion 37. ), And then is guided to the guide wall 38 to be collected in the inner circumferential side portion of the thin plate portion 37.

On the contrary, as indicated by the dotted arrows in FIG. 3, when the rotor 31 rotates clockwise, the resistance portion 36 rotates clockwise in the silicone oil 21, and at this time, the resistance portion ( The viscous and shear resistance of the silicone oil 21 acts on the rotor 36 to brake the rotation of the rotor 31.

Therefore, the driven gear 71 attached to the rotor 31 brakes the rotation or movement of the gear, rack, etc. to which the driven gear 71 is engaged to make the rotation or movement slow.

As the negative pressure portion is generated downstream of the outside of the resistance portion 36 when the rotor 31 rotates clockwise in this manner, the air A mixed into the case 11 at the time of assembly is indicated by a dotted line. It follows the negative pressure part and moves.

By the way, when the rotor 31 rotates clockwise, the thin plate portion 37 and the guide wall 38 are formed on the upper side of the resistance portion 36 as shown in FIG. As shown by the solid arrows in FIG. 3, the air represented by the solid line following the negative pressure portion generated downstream of the resistance section 36 and moved in the counterclockwise direction is moved to the thin plate portion 37. ), And then is guided to the guide wall 38 to be collected in the inner circumferential side portion of the thin plate portion 37.

The air A collected in the inner circumferential side portion of the thin plate portion 37 thus generates almost no negative pressure on the inner circumferential side portion of the thin plate portion 37 even when the rotor 31 rotates. ) Will stay on the inner circumferential side.

The air A collected at the inner circumferential side of the thin plate portion 37 is held in the air holding grooves 13a and 54 and stays in the air holding grooves 13a and 54.

As described above, according to the first embodiment of the present invention, the thin plate portion 37 is formed in the resistance portion 36, and the air A in the case 11 is thin due to the rotation of the rotor 31. Since the guide wall 38 is formed in a vortex shape toward the inner circumferential side to move toward the inner circumferential side of the portion 37, air A can be collected and stayed on the inner circumferential side of the thin plate portion 37.

Therefore, even if the rotor 31 rotates in both directions, the air A mixed in the case 11 does not pass over the resistance portion 36, thereby resulting from the air A mixed in the case 11. It is possible to prevent the occurrence of noise, and to keep the air A in a portion where the negative pressure is not generated (inner circumferential side portion of the thin plate portion 37).

In addition, since the air holding grooves 13a and 54 are formed, the air A can be held in the air holding grooves 13a and 54 so as to stay in the air holding grooves 13a and 54.

(Second embodiment)

5 is a cross-sectional view of a rotary damper according to a second embodiment of the present invention, FIG. 6 is an enlarged cross-sectional view of the rotor shown in FIG. 5, FIG. 7 is a plan view of the rotor shown in FIG. 6, and FIG. 8 is a It is a bottom view, the same code | symbol is attached | subjected about the same or substantial part as 1st Example, and the description is abbreviate | omitted.

The rotor 31 in the second embodiment is accommodated in the case 11, and is formed in the shaft portion 32 and part of the shaft portion 32 protruding outward from the case 11, and the case. The planar shape which moves in the silicone oil 21 in 11 is comprised by the flat-plate resistance part 36A which forms a circle.

The resistance portion 36A is an air chamber that collects four arc-shaped holes 39 (the air A mixed into the case 11 at the time of assembly) at an initial stage on a concentric circle on the inner circumferential side as an initial stage. Function], and four arc-shaped protrusions 40 are formed on the outer side of the arc-shaped hole 39 at an angle slightly larger than this, at intervals of 90 degrees on the concentric circles. The annular protrusion wall 42 is formed in the outer periphery with predetermined space | interval.

Moreover, the arc-shaped protrusion 40 and the annular protrusion wall 42 are formed in the upper and lower surfaces of the resistance part 36A, as shown to FIG.

Then, an annular air rectifying portion 43 is formed between the arc-shaped protrusion 40 and the annular protruding wall 42 with a concave portion, and the inner circumference of the resistance portion 36A is formed between the arc-shaped protrusions 40. The concave groove 41 is formed as a guide means which passes from the side to the outer peripheral side.

In addition, the air holding grooves 13a and 54 are formed on the outer circumferential side of the bottom portion 13 and the cap 51 in correspondence with the air rectifying portion 43.

Subsequently, since the assembly of the rotary damper D is the same as in the first embodiment, the description thereof is omitted and the operation will be described.

When the rotor 31 rotates clockwise or counterclockwise, the resistance portion 36A rotates clockwise or counterclockwise in the silicone oil 21, and at this time, the silicone oil is applied to the resistance portion 36A. As the viscous and shear resistances of (21) act, the rotation of the rotor 31 is braked.

Therefore, the driven gear 71 attached to the rotor 31 brakes the rotation or movement of the gear, rack, etc. to which the driven gear 71 is engaged to make the rotation or movement slow.

In this way, when the rotor 31 rotates, air A mixed in the case 11 may flow out of the arc hole 39 at the time of assembly assembled in the arc hole 39.

In this way, the air A flowing out of the arc-shaped hole 39 is directed to the outer circumferential side where negative pressure is likely to occur, and the inner circumferential side of the arc-shaped protrusion 40 circumferentially passes through the concave groove 41. It flows into the annular air rectifying part 43, and collects in this air rectifying part 43.

The air A collected in the air rectifying part 43 is held in the air holding grooves 13a and 54 and stays in the air holding grooves 13a and 54.

As described above, according to the second embodiment of the present invention, the air rectifying portion 43 is formed on the outer circumferential side of the resistance portion 36A, and the concave grooves through which the guide means pass from the inner circumferential side of the resistance portion 36A to the outer circumferential side. Since it is set as (41), the air A mixed in the case 11 can be directed to the air rectifying part 43 side through the recessed groove 41, and can stay in this air rectifying part 43. FIG.

And since the annular protrusion wall 42 was formed in the resistance part 36A of the outer side of the recessed groove 41, the air A mixed in the case 11 is the inner peripheral surface of the case 11 which is a torque generating part. And the inside of the air rectifying portion 43 so as not to flow between the outer peripheral surface of the resistance portion 36A.

In addition, since the air holding grooves 13a and 54 are formed on the outer circumferential side of the bottom surface of the case 11 and the outer circumferential side of the lower surface (ceiling surface) of the cap 51, the air mixed in the case 11 ( A) can be held in the air holding grooves 13a and 54 so as to stay in the air holding portion 43.

In the above embodiment, the thin plate portion 37 is extended to the outer peripheral end of the resistor portion 36, but the thin plate portion 37 extends to the middle of the resistor portion 36, and the thin plate portion 37 Guiding means, such as a groove | channel, continued to the edge may extend to the outer peripheral end of the resistance part 36.

And although the example which formed the guide wall 38 as a guide means in vortex form was shown, since it is only necessary to guide air A to the inner peripheral side, it may be linear form.

Moreover, although the example which made the air storage part into the thin plate part 37 which consists of recessed parts, and the annular air storage part 43 was shown, it functions similarly also when an air storage part is used as a hole, and the air storage part 43 is arcuate-shaped. It may be.

In addition, although the shaft support portion 16 is formed in the case 11 and the recess portion 33 is formed in the shaft portion 32, an example in which the rotor 31 is rotatably supported is shown. The shaft support portion may be formed in the shaft portion.

Moreover, although the example in which the resistance parts 36 and 36A were integrally formed in the shaft part 32 was shown, the shaft part and the resistance part are molded separately, for example, the angle | corner of each axis | shaft and a square hole. You may comprise so that it may rotate integrally by a relationship.

Then, the housing is composed of a case 11 and a cap 51, a housing portion 15 of the silicone oil 21 is formed in the case 11, and the shaft portion 32 of the rotor 31 penetrates. Although the through-hole 52 is formed in the cap 51, an example has been shown in which the zero ring 61 prevents leakage of the silicone oil 21 between the cap 51 and the shaft portion 32. The cap may be provided with a housing portion of the silicone oil, a through hole through which the shaft portion of the rotor penetrates the case, and a zero ring may prevent the silicone oil from leaking between the case and the shaft portion.

Moreover, although the example which used the silicone oil 21 as a viscous fluid was shown, other viscous fluids, for example, grease etc. which perform the same function can also be used.

As described above, according to the present invention, since the air rectifying portion formed of the concave portion or the hole is formed in the resistance portion and the guide means for guiding the air in the housing to move to the air rectifying portion is formed by the rotation of the rotor, Air collected in the housing can be collected and stayed in the air rectifying unit. Therefore, even if the rotor rotates in both directions, the air mixed in the housing does not ride over the resistance portion, thereby preventing the occurrence of noise caused by the air mixed in the housing.

Since the air rectifying portion is formed on the inner circumferential side of the resistor portion, and the guide means is a guide wall facing the inner circumferential side in a vortex form at the outer circumferential end of the resistor portion, the air mixed in the housing is directed to the air rectifying portion by the guide wall. It is possible to keep the air entrained in the portion where no negative pressure occurs.

Further, since the air holding part is formed on at least one of the inner circumferential side of the bottom surface of the housing and the inner circumferential side of the ceiling surface of the housing, the air mixed in the housing can be held in the air holding part so as to stay in the air holding part.

In addition, since the air rectifying portion is formed on the outer circumferential side of the resistor portion, and the guide means is a concave groove that passes from the inner circumferential side of the resistor portion to the outer circumferential side, the air entrained in the housing is directed to the air rectifying portion through the concave groove, so as to remain in the air rectifying portion. can do.

And since the annular protrusion wall is formed in the resistance part of the outer side of the concave groove, the air mixed in the housing can be kept in the air rectifying part so as not to flow between the inner circumferential surface of the housing which is the braking torque generating part and the outer circumferential surface of the resistance part. .

In addition, since the air holding part is formed on at least one of the outer circumferential side of the bottom surface of the housing and the outer circumferential side of the ceiling surface of the housing, the air mixed in the housing can be held in the air holding part so as to stay in the air holding part.

1 is a cross-sectional view of a rotary damper according to a first embodiment of the present invention.

2 is an enlarged cross-sectional view of the rotor shown in FIG.

3 is a plan view of the rotor shown in FIG.

4 is a bottom view of the rotor shown in FIG.

5 is a cross-sectional view of a rotary damper according to a second embodiment of the present invention.

6 is an enlarged cross-sectional view of the rotor shown in FIG.

7 is a plan view of the rotor shown in FIG.

FIG. 8 is a bottom view of the rotor shown in FIG. 6

Explanation of symbols on the main parts of the drawings

D-Rotary Damper 11-Case (Housing)

12-Case body 13-Bottom

13a-Air holding groove (Air holding part) 14-Cylindrical wall part

14a-protruding wall 15-receptacle

16-shaft support 17-mounting flange

18-Mounting Holes 21-Silicone Oil (Viscous Fluid)

31-rotor 32-shaft

33-recess 34-cut I step

35-fit groove 36,36A-resistor

37-thin plate (air rectifier)

38-guide wall (guide) 39-arc hole (air chamber)

40-arc-shaped protrusion 41-concave groove

42-annular protruding wall 43-air rectifier

51-cap (housing) 52-through-hole

53-Step 54-Air retaining groove

55-Recessed recess 61-0 ring (sealed)

71-Driven Gear 72-Mounting Hole

73-Fitted Stone A-Air

Claims (6)

A rotor having a housing, a viscous fluid accommodated in the housing, a shaft part accommodated in the housing and protruding from the housing, the resistance part moving in the viscous fluid in the housing, and the shaft and the housing In the rotary damper made of a sealing member for preventing the viscous fluid from leaking between, An air rectifying portion formed of a recess or a hole in the resistance portion; And a guide means for guiding the air in the housing to move to the air rectifying part by the rotation of the rotor. The method according to claim 1, The air rectifying portion is formed on the inner circumferential side of the resistance portion, The guide damper is a rotary damper, characterized in that the guide wall toward the inner circumferential side in a spiral shape at the outer peripheral end of the resistance portion. The method according to claim 1 or 2, And an air holding part formed on at least one of an inner circumferential side of the bottom surface of the housing and an inner circumferential side of the ceiling surface of the housing. The method according to claim 1, The air rectifying portion is formed on the outer circumferential side of the resistance portion, And the guide means is a concave groove passing from the inner circumference side to the outer circumference side of the resistance portion. The method according to claim 4, A rotary damper, characterized in that an annular protruding wall is formed in the resistance portion on the outer side of the concave groove. The method according to claim 4 or 5, And an air holding part formed on at least one of an outer circumferential side of the bottom surface of the housing and an outer circumferential side of the ceiling surface of the housing.