JP4734087B2 - Automatic shutter device and ventilation device using the same - Google Patents

Description

  The present invention relates to an automatic shutter device that is installed in a vent and automatically controls ventilation between indoors and outdoors of a building in accordance with an air temperature, and a ventilation device using the same.

  2. Description of the Related Art Conventionally, an automatic shutter device (ventilator automatic opening / closing device) that is installed in a vent and automatically controls ventilation between indoors and outdoors according to the temperature is known (for example, see Patent Document 1).

  In the automatic shutter device disclosed in Patent Document 1, a thin plastic circular mounting base plate is fixed so as to cover a circular ventilation hole (ventilation opening). In this circular mounting base plate, a plurality of ventilation windows formed radially in the radial direction are arranged at predetermined intervals along the circumferential direction of the mounting base plate. A rotating shaft is provided at the center of the mounting base plate, and a thin plastic on-off valve plate for opening and closing the ventilation window of the mounting base plate is rotatably attached to the rotating shaft. In this on-off valve plate, a plurality of valve pieces having substantially the same shape as the ventilation window of the mounting base plate are formed at predetermined intervals in the rotation direction, and the outer peripheral portion of the on-off valve plate (valve piece) and the mounting base The plates are connected by a coil spring-like actuating element made of a shape memory alloy. Then, the opening / closing valve plate is rotated by utilizing the expansion and contraction of the operating element due to a change in temperature, so that the vent window of the mounting base plate is opened and closed using the valve piece of the opening / closing valve plate.

That is, in the automatic shutter device disclosed in Patent Document 1, when the air temperature is higher than a predetermined temperature, the opening / closing valve plate is rotated by the contraction of the operating element to move the valve piece, thereby venting the mounting base plate. On the other hand, when the air temperature is lower than a predetermined temperature, the opening / closing valve plate is rotated in the reverse direction by the extension of the operating element, and the vent window of the mounting base plate is closed by the valve piece. Thereby, ventilation between indoors and outdoors is taken when the temperature is high, and ventilation between indoors and outdoors is cut off when the temperature is low to obtain a heat insulating effect.
Japanese Patent Laid-Open No. 3-51444

  However, in the conventional automatic shutter device disclosed in Patent Document 1, both the mounting base plate and the on-off valve plate are formed of thin plastic plates, and it is considered that the heat insulation is not so high. Accordingly, there is a problem that it is difficult to improve the heat insulating effect even if the ventilation window of the mounting base plate is closed by the valve piece of the opening / closing valve plate when the temperature is low. In addition, due to the fact that the heat insulation is not so high in the mounting base plate and on-off valve plate made of a thin plastic plate, warm air on the indoor side is near the mounting base plate and on-off valve plate when the outdoor temperature is low. There is a problem that condensation occurs when cooled.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an automatic shutter device capable of improving the heat insulation effect when the temperature is low and suppressing condensation, and the use thereof. Is to provide a venting device.

In order to achieve the above object, an automatic shutter device according to the present invention includes a substantially cylindrical exterior body that is installed in a ventilation hole that penetrates an outer wall between the inside and outside of a building so as to extend along the penetration direction. Opened ventilation portions that are fixed inside the body and allow ventilation between indoors and outdoors and shielding portions that block ventilation are alternately formed around the central axis of the exterior body along the circumferential direction of the exterior body. The first shutter unit and the first shutter unit in the exterior body are provided adjacent to the indoor side or the outdoor side so as to be rotatable around the central axis, and ventilated at predetermined intervals along the rotation direction. A second shutter portion having a shielding piece for blocking, and a second shutter portion provided in the exterior body so as to be positioned on the opposite side of the first shutter portion with respect to the second shutter portion, and when the temperature is higher than a predetermined temperature , the second shutter portion Shutter part is first with shielding piece A rotating device for rotating the second shutter unit in a direction in which the shielding piece and the ventilation portion of the first shutter unit overlap when the temperature is lower than a predetermined temperature while rotating in the direction in which the shielding unit of the shutter unit overlaps. The shielding part of the first shutter part and the shielding piece of the second shutter part are both formed of a heat insulating material, and the rotating device is installed in the exterior body, and the second shutter part in the indoor / outdoor direction. A housing formed with a housing chamber that opens on the opposite side of the housing, a housing cover that is attached to the housing so as to cover the opening on the side opposite to the second shutter portion of the housing chamber, and can be moved forward and backward with respect to the cylinder portion A thermo element having a temperature-sensitive member that is accommodated in a piston part and a cylinder part to be attached and expands and contracts in accordance with the temperature level, and is accommodated in the accommodation chamber, together with the cylinder part An interlocking portion that moves linearly in a direction substantially perpendicular to the axis, and a rotating portion that is attached to the second shutter portion and rotates around the central axis together with the second shutter portion, It has a long hole extending in a direction substantially perpendicular to the central axis and perpendicular to the moving direction of the interlocking portion. The rotating portion is inserted into the long hole so as to be freely movable, and the interlocking portion is a cylinder. The linear movement of the interlocking part is performed around the central axis of the rotating part by moving along the extending direction of the elongated hole while moving with the interlocking part along with the movement of the interlocking part. It has an operation shaft which converts into the rotation operation .

In the automatic shutter device of the present invention, as described above, good heat insulation can be obtained by forming both the shielding part of the first shutter part and the shielding piece of the second shutter part with a heat insulating material. Accordingly, when the temperature is low, the second shutter portion is rotated in a direction in which the shielding piece of the second shutter portion and the ventilation portion of the first shutter portion overlap with each other by the rotating device, and the ventilation portion of the first shutter portion is thereby changed to the second. When closed by the shielding piece of the shutter part, the heat insulating effect can be improved by the shielding part of the first shutter part and the shielding piece of the second shutter part having good heat insulation. Further, at that time, due to the shielding part of the first shutter part and the shielding piece of the second shutter part having good heat insulation properties, warm air on the indoor side causes the warm air on the indoor side even if the outdoor temperature is low. Since it can suppress that it cools in the vicinity of a part and a 2nd shutter part, dew condensation can be suppressed. Further, unlike the coil spring made of shape memory alloy, the thermo element can generate a large force for moving the cylinder portion by utilizing expansion of a temperature sensitive member made of, for example, wax. As a result, the large force can be transmitted to the second shutter portion to rotate the second shutter portion, so that the frictional force applied to the second shutter portion is large, the size of the second shutter portion is large, etc. Even when a large force is required to rotate the second shutter portion due to the above, the second shutter portion can be reliably rotated. In this automatic shutter device, the interlocking portion and the turning portion easily convert the linear movement operation along the piston portion of the cylinder portion of the thermo element into the turning operation around the central axis and the second operation. The second shutter portion can be rotated around the central axis by transmitting to the shutter portion.

Further, in the automatic shutter device, preferably, when the air temperature is higher than the predetermined temperature, the thermo-element, the cylinder portion in a direction in which the protruding amount from the cylinder portion of the piston portion is increased according to the expansion of the temperature-sensitive member together move linearly, by the moving operation is transfer us is converted into rotational movement about the central axis to the rotating portion from the interlocking portion, the second shutter portion, the shielding piece and the first shutter portion When the air temperature is lower than a predetermined temperature, the cylinder part is moved in the direction in which the amount of protrusion from the cylinder part of the piston part decreases in response to the shrinkage of the temperature sensitive member when the air temperature is lower than the predetermined temperature. by but it while moving linearly, the moving operation is transfer us is converted into rotational movement about the central axis to the rotating portion from the interlocking portion, the second shutter portion, the shielding piece and first A vent of Yatta portion is rotated in a direction to overlap.

In the configuration in which the rotating device includes the interlocking portion and the rotating portion, preferably, the interlocking portion and the rotating portion are inserted into the elongated hole at a position near the central axis in the radial direction of the exterior body. It is connected by. With this configuration, unlike the case where the interlocking portion and the rotating portion are connected at a position far from the central axis in the radial direction of the exterior body, even when the cylinder portion and the interlocking portion of the thermo element move a little. The rotation distance of the rotation unit can be increased. As a result, even if the cylinder part and the interlocking part of the thermo element move only slightly due to a slight change in temperature, the rotating part and the second shutter part can be rotated greatly in response to the change well. The ventilation part of the first shutter part can be opened and closed by the shielding piece of the second shutter part.

  In the automatic shutter device, preferably, the first shutter part and the second shutter part are formed in substantially the same shape, and the shielding part of the first shutter part and the shielding piece of the second shutter part are both The fan is formed in a substantially fan shape so as to extend from the central axis side to the outer side in the radial direction of the exterior body, and the ventilation portion of the first shutter portion is formed by a space between adjacent shielding portions along the circumferential direction of the exterior body. . If comprised in this way, a common member can be used as a 1st shutter part and a 2nd shutter part by forming a 1st shutter part and a 2nd shutter part in substantially the same shape. Thereby, the manufacturing process of an automatic shutter apparatus can be simplified compared with the case where a 1st shutter part and a 2nd shutter part are formed separately.

  The ventilation device of the present invention includes the automatic shutter device, and further includes a manual shutter device provided on the indoor side or the outdoor side of the automatic shutter device and having a ventilation window that can be manually opened and closed. Yes. In this ventilation device, when the temperature is low, in addition to the heat insulation effect by the automatic shutter device, a further heat insulation effect can be obtained by manually closing the ventilation window of the manual shutter device.

  In this case, preferably, the frame further includes a frame body that is fixed to the vent and has a cylindrical portion that houses the automatic shutter device, the manual shutter device is detachably attached to the frame body, It is fixed to the manual shutter device without being fixed to the frame. With this configuration, even when the manual shutter device is provided on the indoor side (outdoor side) of the automatic shutter device, the automatic shutter device and the manual shutter device are integrated into the indoor side from the frame fixed to the vent hole. It can be removed to the (outdoor side). That is, even when the manual shutter device is provided on the indoor side (outdoor side) of the automatic shutter device, it is easy to remove the manual shutter device from the frame without performing the operation of removing the automatic shutter device from the frame. Maintenance can be performed by removing the automatic shutter device indoors (outdoors).

  As described above, with the automatic shutter device and the ventilation device according to the present invention, it is possible to improve the heat insulating effect and suppress the condensation when the temperature is low.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an exploded perspective view showing a configuration of a ventilation device according to an embodiment of the present invention. FIG. 2 is a cross-sectional view showing a state in which the ventilation device according to the embodiment shown in FIG. 3-20 is a figure for demonstrating the structure of the automatic shutter apparatus used for the ventilation apparatus by one Embodiment shown in FIG. First, with reference to FIGS. 1-20, the structure of the ventilation apparatus by one Embodiment of this invention is demonstrated.

  As shown in FIG. 1, the ventilation device according to the present embodiment includes an automatic shutter device 1, a frame body 2, a manual shutter device 3, a filter 4, and a cover 5. As shown in FIG. 2, this ventilation device is installed in a ventilation hole 510 that penetrates an outer wall 500 between the inside and outside of a building, and has a function of controlling ventilation between the inside and outside of the building.

  The automatic shutter device 1 has a function of automatically controlling ventilation according to the temperature. Specifically, as shown in FIGS. 3 to 10, the automatic shutter device 1 includes an exterior body 11, a first shutter portion 12, a second shutter portion 13, and a rotating device 14. .

  As shown in FIG. 2, the exterior body 11 is formed in a substantially cylindrical shape, and extends in a cylindrical portion 2 a of the frame body 2, which will be described later, installed in the air vent 510 along the penetration direction of the air vent 510. Installed. Further, as shown in FIGS. 3 and 4, three connecting portions 11 a and a shaft cover portion 11 b are integrally formed in the vicinity of the indoor side end portion of the inner peripheral surface of the exterior body 11. The shaft cover portion 11 b is formed in a circular shape when viewed from the indoor side, and is arranged so that the center thereof is located on the central axis of the exterior body 11.

  Moreover, the shaft cover part 11b is installed so that the indoor side of the rotating shaft 23 mentioned later may be covered. The three connecting portions 11 a connect the shaft cover portion 11 b and the inner peripheral surface of the exterior body 11. The three connecting portions 11a are arranged at equal intervals in the circumferential direction of the shaft cover portion 11b and the exterior body 11, and extend in the radial direction from the outer peripheral surface of the shaft cover portion 11b to the inner peripheral surface of the exterior body 11. Is formed. In addition, four locking portions 11c are provided at equal intervals on the peripheral edge portion of the indoor side end portion of the exterior body 11.

  The first shutter portion 12 is fixed to the outdoor side of the shaft cover portion 11 b in the exterior body 11. In the first shutter portion 12, an open ventilation portion 12 a for taking ventilation between indoors and outdoors and a shielding portion 12 b for blocking ventilation are alternately arranged around the central axis of the exterior body 11 along the circumferential direction of the exterior body 11. Is formed. That is, as shown in FIG. 11, the first shutter portion 12 includes a substantially cylindrical central portion 12c arranged so that the central axis thereof coincides with the central axis of the exterior body 11, and the central portion 12c. It has three substantially fan-shaped shielding portions 12b extending from the outer peripheral surface to the outer side in the radial direction of the exterior body 11. The three shielding portions 12b are arranged at equal intervals around the central portion 12c along the circumferential direction of the exterior body 11. And the ventilation part 12a is formed of the space between the shielding parts 12b adjacent along the circumferential direction of the exterior body 11. FIG.

  Further, an axial hole 12d penetrating in the central axis direction of the exterior body 11 is formed at the center position of the central portion 12c of the first shutter portion 12, and the shaft hole 12d extends from the axial hole 12d to the three shielding portions 12b side. A hole 12e is formed. A bearing member 12f (see FIG. 6) is mounted in the shaft hole 12d, and the bearing member 12f is fixed in a state of being inserted into a rotating shaft 23 described later. As described above, the first shutter portion 12 is fixed in a state where the first shutter portion 12 is inserted through the rotation shaft 23 in the exterior body 11. Further, as shown in FIGS. 11 and 12, protrusions 12 g are respectively formed on the indoor-side surfaces of both end portions in the circumferential direction of the exterior body 11 of each shielding portion 12 b. The protruding portion 12g is formed to extend from the central portion 12c side of the shielding portion 12b to an end portion on the radially outer side.

  In addition, the second shutter portion 13 is disposed adjacent to the outdoor side of the first shutter portion 12 in the exterior body 11 and is rotatably provided around the central axis of the exterior body 11. The second shutter portion 13 is configured to be rotatable around the central axis of the exterior body 11 by being rotatably attached to a later-described rotation shaft 23 disposed at a position corresponding to the central axis of the exterior body 11. ing.

  In the present embodiment, the second shutter portion 13 and the first shutter portion 12 are formed in the same shape. That is, as shown in FIG. 11, the second shutter portion 13 includes three substantially sector-shaped shielding pieces 13 b and a substantially cylindrical central portion 13 c that have the same shape as the shielding portion 12 b and the central portion 12 c of the first shutter portion 12. have. The second shutter portion 13 has a shaft hole 13d, a mounting hole 13e, and a protruding portion 13g corresponding to the shaft hole 12d, the hole portion 12e, and the protruding portion 12g of the first shutter portion 12, respectively. The three shielding pieces 13b of the second shutter portion 13 are arranged around the central portion 13c with a space (interval) of the same shape as the ventilation portion 12a of the first shutter portion 12 along the rotation direction. Yes. The second shutter part 13 is provided to open and close the ventilation part 12a of the first shutter part 12 with the shielding piece 13b while being rotated around a rotation shaft 23 described later.

  Further, the length of the shielding piece 13b of the second shutter portion 13 (the shielding portion 12b of the first shutter portion 12) along the circumferential direction of the exterior body 11 is the length of the exterior body 11 of the ventilation portion 12a of the first shutter portion 12. The length of the protrusion 13g (protrusion 12g) is larger than the length along the circumferential direction. That is, in a state where the ventilation piece 12b of the first shutter portion 12 is overlapped with the ventilation portion 12a of the first shutter portion 12 and the ventilation portion 12a of the first shutter portion 12 is closed, as shown in FIGS. The formation region of the protruding portion 13g of the shielding piece 13b of the second shutter portion 13 and the formation region of the protruding portion 12g of the shielding portion 12b of the first shutter portion 12 are configured to overlap.

  In the present embodiment, the first shutter portion 12 and the second shutter portion 13 are each formed of a heat insulating material made of foamed resin. In addition, as foamed resin which comprises the 1st shutter part 12 and the 2nd shutter part 13, polyolefin, such as polyethylene and a polypropylene, is used. In addition, as the foamed resin, materials other than those described above can be used. For example, polystyrene or polyurethane can be used. Further, the central portion 12c and the shielding portion 12b of the first shutter portion 12 and the central portion 13c and the shielding piece 13b of the second shutter portion 13 are all formed to a thickness of about 10 mm.

  When the air temperature is higher than a predetermined temperature, the rotating device 14 is configured so that the shielding piece 13b of the second shutter portion 13 and the shielding portion 12b of the first shutter portion 12 overlap each other as shown in FIG. When the air temperature is lower than a predetermined temperature, the second shutter portion 13 is connected to the shielding piece 13b and the first shutter portion 12 as shown in FIG. It has a function of closing the ventilation part 12a of the first shutter part 12 by rotating in a direction (B direction) where the ventilation part 12a overlaps. The rotation device 14 includes a housing 21, a housing cover 22, a rotation shaft 23, a thermo element 24, and an operation transmission unit 25.

  As shown in FIG. 6, the housing 21 is installed on the outdoor side from the center in the exterior body 11. Further, as shown in FIG. 9, the housing 21 is formed in a substantially T shape when viewed from the outdoor side, and most of the housing 21 overlaps a shielding portion 12b of the first shutter portion 12 and a rotating member 36 described later. Are arranged as follows. Thereby, when ventilating through the ventilation part 12a of the 1st shutter part 12, the housing 21 is comprised so that ventilation may not be prevented as much as possible.

  Further, as shown in FIG. 13, a housing chamber 21e composed of a plurality of inner walls 21a to 21d is formed on the outdoor side of the housing 21, and a thermo element 24 and operation transmission to be described later are transmitted to the housing chamber 21e. The interlocking member 35 of the part 25 is accommodated. Further, a guide groove 21f for guiding the interlocking member 35 is formed at the bottom of the storage chamber 21e where the interlocking member 35 is accommodated.

  In addition, a floating hole 21g penetrating in the direction of the central axis is formed at a position adjacent to the central axis of the exterior body 11 of the storage chamber 21e. The idle hole 21g is formed in an arc shape along the rotation direction of the second shutter portion 13 (the circumferential direction of the exterior body 11), and is formed substantially parallel to the moving direction of the interlocking member 35 described later. ing.

  As shown in FIG. 6, the housing cover 22 is attached to the outdoor side of the housing 21 and covers the outdoor side of the housing chamber 21 e of the housing 21. As shown in FIG. 7, two guide grooves 22a linearly extending in the moving direction of the interlocking member 35 are formed in parallel at a predetermined interval at positions corresponding to the interlocking member 35 described later of the housing cover 22. Has been. Further, as shown in FIG. 14, the rotation shaft 23 protrudes along the central axis at a position corresponding to the central axis of the exterior body 11 on the indoor side surface of the housing 21. As described above, the second shutter portion 13 is rotatably attached to the rotation shaft 23 via a rotation member 36 described later, and the first shutter portion 12 is fixed via a bearing member 12f. Yes.

  The thermo element 24 is a drive source of the rotation device 14 according to the present embodiment, and as shown in FIGS. 15 and 16, a cylinder portion 31, a piston portion 32, a temperature sensitive member (not shown), a main body, and the like. A spring 33 and a relief spring 34 are included. The piston part 32 is attached to the cylinder part 31 so as to be able to advance and retreat. The cylinder part 31 and the piston part 32 are disposed in the housing chamber 21e of the housing 21 along a direction substantially perpendicular to the central axis direction of the exterior body 11. Is housed in. Further, the end portion of the piston portion 32 opposite to the cylinder portion 31 is fixed to the inner wall 21 a of the housing 21.

  The cylinder portion 31 is slidably supported by the corresponding inner wall 21 b of the housing 21, and is configured to be linearly movable along the piston portion 32. Further, the temperature sensitive member (not shown) is accommodated in the cylinder portion 31 and is made of wax or the like that expands and contracts according to the temperature. In the thermo element 24, the cylinder part 31 is linearly moved along the piston part 32 so that the amount of protrusion of the piston part 32 from the cylinder part 31 increases or decreases by utilizing the expansion and contraction of the temperature sensing member (not shown). It is configured to be moved. That is, when the temperature is higher than a predetermined temperature, the direction in which the protrusion amount of the piston portion 32 from the cylinder portion 31 increases according to the expansion of the temperature sensing member (not shown) (direction C in FIGS. 15 and 16). When the cylinder portion 31 is linearly moved while the air temperature is lower than a predetermined temperature, the amount of protrusion of the piston portion 32 from the cylinder portion 31 decreases in accordance with the contraction of the temperature sensing member (not shown). The cylinder part 31 is configured to move in the direction D (FIG. 15 and FIG. 16).

  The main spring 33 is configured by a compression coil spring, and is provided between the cylinder portion 31 and the inner wall 21 b of the housing 21. The main spring 33 always urges the cylinder portion 31 toward the piston portion 32 (D direction). Therefore, when the cylinder part 31 moves in the C direction so that the temperature sensing member (not shown) in the cylinder part 31 expands and the protruding amount of the piston part 32 from the cylinder part 31 increases, The main spring 33 is configured to move while being contracted against the urging force of the main spring 33. Further, the main spring 33 moves the cylinder portion 31 so that when the temperature-sensitive member (not shown) in the cylinder portion 31 contracts, the protruding amount of the piston portion 32 from the cylinder portion 31 decreases according to the contraction. It also has a function of moving in the D direction.

  The relief spring 34 is constituted by a compression coil spring, and is provided between the cylinder part 31 and a washer 37 described later at the end of the cylinder part 31 opposite to the piston part 32. The relief spring 34 absorbs the force generated by the movement of the cylinder 31 when the temperature sensing member (not shown) in the cylinder 31 is greatly expanded in the C direction, and the housing 21 The inner wall 21c is provided to prevent the inner wall 21c from being damaged.

  In the present embodiment, the motion transmission unit 25 (see FIG. 9) performs a linear movement operation along the piston portion 32 of the cylinder portion 31 of the thermoelement 24 around the central axis (rotation shaft 23) of the exterior body 11. It has a function of converting it into a rotating operation and transmitting it to the second shutter unit 13. The motion transmission unit 25 rotates around the central axis (rotating shaft 23) of the exterior body 11 together with the interlocking member 35 (interlocking part) that moves linearly together with the cylinder part 31 of the thermo element 24 and the second shutter part 13. A rotating member 36 (rotating part) that moves. In the present embodiment, the interlocking member 35 and the rotating member 36 perform a linear movement operation of the interlocking member 35 around the central axis (rotating shaft 23) of the exterior body 11 of the rotating member 36. It is concatenated to convert to.

  As shown in FIGS. 15 and 16, the interlocking member 35 is fixed to the end of the thermoelement 24 opposite to the piston portion 32 of the cylinder portion 31, and moves in the same direction in conjunction with the cylinder portion 31. It is configured as follows. The interlocking member 35 is formed in a substantially L shape, and is disposed perpendicular to the cylinder portion 31 of the thermoelement 24 and fixed to the cylinder portion 31, and is perpendicular to the longitudinal portion 35 a. And a short portion 35b bent toward the piston portion 32 side. Further, a groove portion 35c is formed in the extending portion 35a of the interlocking member 35 along the extending direction thereof, and a washer 37 attached to the end of the cylinder portion 31 is fitted into the groove portion 35c, whereby the interlocking member The longitudinal part 35a of 35 and the cylinder part 31 are being fixed.

  As shown in FIGS. 17 and 18, the longitudinal portion 35 a of the interlocking member 35 includes one rail portion 35 d and a pair of rail portions 35 e arranged in parallel to the moving direction of the cylinder portion 31 and the interlocking member 35. Are protruded from the surface arranged on the outdoor side and the surface arranged on the indoor side, respectively. The one rail portion 35d and the pair of rail portions 35e are slidably fitted in the guide groove 21f of the housing portion 21 and the guide groove 22a of the housing cover 22, respectively. Thereby, the interlocking member 35 is configured to move along the guide groove 21 f of the housing 21 and the guide groove 22 a of the housing cover 22 when moving in the CD direction in FIGS. 15 and 16.

  Further, an elongated hole 35f extending in a direction substantially perpendicular to the central axis direction of the exterior body 11 and perpendicular to the moving direction of the interlocking member 35 is formed at the end of the short portion 35b of the interlocking member 35. . The long hole 35 f is provided at a position overlapping the idle hole 21 g of the housing 21 in a state where the interlocking member 35 is accommodated in the housing 21.

  Further, as shown in FIG. 19, the rotating member 36 includes a disc-shaped base portion 36b having a through hole 36a provided at the center, and three first attachments protruding from the surface of the base portion 36b on the outdoor side. A portion 36c, three second mounting portions 36d, and a columnar operating shaft 36e projecting on the indoor side surface of the base portion 36b. The rotation member 36 is rotatably provided around the rotation shaft 23 along the circumferential direction of the exterior body 11 by inserting the rotation shaft 23 into the through hole 36a of the base portion 36b.

  The first mounting portion 36 c and the second mounting portion 36 d are portions for mounting the rotating member 36 to the second shutter portion 13. As shown in FIG. 20, the first mounting portions 36c are provided at equal intervals along the peripheral edge of the surface on the outdoor side of the base portion 36b, and are formed in an arc shape. The second mounting portions 36d are provided at regular intervals around the through holes 36a on the surface on the outdoor side of the base portion 36b, and are formed in a columnar shape. The three first mounting portions 36c are respectively inserted into regions between the corresponding adjacent shielding pieces 13b of the second shutter portion 13 (see FIG. 11), and the three second mounting portions 36d are respectively The second shutter part 13 is inserted into the corresponding three mounting holes 13e. Thereby, the rotation member 36 is attached to the second shutter portion 13. Further, as shown in FIG. 19, the operating shaft 36e is provided adjacent to the through hole 36a of the base portion 36b. The operating shaft 36e is inserted through the free hole 21g of the housing 21 and the long hole 35f of the interlocking member 35 so as to be freely movable.

  That is, in the present embodiment, the interlocking member 35 and the rotating member 36 are coupled to each other at a position in the vicinity of the central axis (the rotating shaft 23) in the radial direction of the exterior body 11 via the operating shaft 36e of the rotating member 36. ing. In the present embodiment, as shown in FIGS. 15 and 16, when the interlocking member 35 linearly moves in the CD direction, the operation inserted through the long hole 35 f of the interlocking member 35 and the idle hole 21 g of the housing 21. The rotation member 36 (see FIG. 9) is configured to rotate by moving the shaft 36e along the arcuate idle hole 21g. With this configuration, the linear movement operation of the interlocking member 35 and the interlocking member 35 so as to be able to be converted into a rotational operation around the central axis (rotating shaft 23) of the exterior body 11 of the rotating member 36. The moving member 36 is connected.

  Further, as shown in FIG. 1, the frame 2 is constituted by a cylindrical portion 2a having a cylindrical shape and a substantially square frame portion 2b provided on the indoor side of the cylindrical portion 2a. 2a is fixed to the vent hole 510 so as to be located in the vent hole 510 (see FIG. 2). The automatic shutter device 1 is accommodated in the cylindrical portion 2 a of the frame body 2 located in the vent hole 510. A pair of locking portions 2c are provided on the indoor side surface of the frame portion 2b so as to face each other with the formation region of the cylindrical portion 2a interposed therebetween.

  The manual shutter device 3 is provided for manually switching between a ventilation state and a ventilation blocking state manually. The manual shutter device 3 is provided on the indoor side of the frame body 2 and is detachably attached to the frame body 2. In the present embodiment, the automatic shutter device 1 is fixed to the manual shutter device 3 without being fixed to the frame body 2. The manual shutter device 3 includes a fixed shutter unit 40 and a manual shutter unit 50. The fixed shutter portion 40 includes a substantially square outer frame 41, a substantially circular support portion 42 formed inside the outer frame 41, and a shaft portion 43 provided at the center position of the support portion 42. Yes. In addition, a pair of locked portions 41 a are provided on the outer surface of the outer frame 41 of the frame body 2 at positions corresponding to the pair of locked portions 2 c of the frame body 2.

  In the present embodiment, the manual shutter device 3 (fixed shutter portion 40) is attached to and detached from the frame 2 by the pair of locked portions 41a being locked to the pair of locking portions 2c of the frame 2. It is attached as possible. In addition, on the inner side of the support portion 42 of the fixed shutter portion 40, a ventilation window 44 opened in a fan shape around the shaft portion 43 and a shielding region 45 that blocks ventilation are formed alternately.

  The manual shutter portion 50 is supported by a support portion 42 of the fixed shutter portion 40 so as to be rotatable in the circumferential direction. The manual shutter portion 50 extends from the lower portion of the disc portion 51 to the indoor side and further downwards therefrom. And an extended grip 52. A through hole 53 is provided at the center of the disk part 51, and the shaft part 43 of the fixed shutter part 40 is inserted into the through hole 53. Accordingly, the disk portion 51 is configured to rotate along the support portion 42 around the shaft portion 43 of the fixed shutter portion 40.

  Further, around the through hole 53 of the disk part 51, a ventilation area 54 opened in a fan shape and a shielding area 55 for blocking the ventilation are alternately formed. Further, the grip portion 52 is arranged so that the lower end thereof protrudes from the lower surface of the cover 5 described later. Thus, the manual shutter portion 50 can be rotated in the direction of the arrow in FIG. 1 by gripping and operating the grip portion 52. By rotating the manual shutter unit 50, the ventilation window 44 of the fixed shutter unit 40 can be opened and closed by the shielding area 55 of the manual shutter unit 50 so that the ventilation state and the ventilation blocking state can be switched. It is configured.

  The filter 4 is installed on the indoor side of the manual shutter device 3 and is provided to remove dust contained in the air. The cover 5 is provided on the innermost side of the ventilation device. The cover 5 is formed in a substantially square shape when viewed from the indoor side, and is fitted to the frame portion 2 b of the frame body 2. Further, an opening 5a is formed in the outer peripheral portion of the cover 5, and the ventilation is performed through the opening 5a.

  Next, the operation of the automatic shutter device 1 used in the ventilation device according to the present embodiment will be described with reference to FIGS.

  In the automatic shutter device 1 according to the present embodiment, when the air temperature is higher than a predetermined temperature, the temperature sensing member accommodated in the cylinder portion 31 of the thermo element 24 expands, so that the cylinder portion 31 becomes the urging force of the main spring 33. While moving in the C direction in FIG. 16 while opposing, the interlocking member 35 also moves in the C direction. At this time, the operating shaft 36e of the rotating member 36 inserted into the long hole 35f of the interlocking member 35 through the loose hole 21g of the housing 21 moves in the long hole 35f of the interlocking member 35 while moving in the arc shape of the housing 21. 16 moves in the direction E in FIG. Accordingly, the rotation member 36 and the second shutter portion 13 rotate about the rotation shaft 23 in the direction A in FIG. As a result, as shown in FIG. 9, the shielding piece 13b of the second shutter portion 13 rotates in a direction overlapping the shielding portion 12b of the first shutter portion 12, and the ventilation portion 12a of the first shutter portion 12 is fully opened. Become.

  On the other hand, when the air temperature is lower than the predetermined temperature, the temperature sensing member accommodated in the cylinder portion 31 of the thermo element 24 contracts, so that the cylinder portion 31 is pushed by the urging force of the main spring 33 and D in FIG. While moving in the direction, the interlocking member 35 also moves in the D direction. At this time, the operating shaft 36e of the rotating member 36 moves in the F direction in FIG. 15 along the idle hole 21g of the housing 21 while freely moving in the elongated hole 35f of the interlocking member 35. Accordingly, the rotation member 36 and the second shutter portion 13 rotate around the rotation shaft 23 in the direction B in FIG. As a result, as shown in FIG. 10, the shielding piece 13b of the second shutter portion 13 rotates in a direction overlapping the ventilation portion 12a of the first shutter portion 12, and the ventilation portion 12a of the first shutter portion 12 is fully closed. It becomes.

  As described above, in the automatic shutter device 1 according to the present embodiment, the ventilation is controlled by automatically opening and closing the ventilation portion 12a of the first shutter portion 12 in accordance with a change in temperature.

  In the present embodiment, as described above, by forming both the shielding portion 12b of the first shutter portion 12 and the shielding piece 13b of the second shutter portion 13 with a heat insulating material, good heat insulating properties can be obtained. Thereby, when the temperature is low, the rotating device 14 rotates the second shutter portion 13 in the direction in which the shielding piece 13b of the second shutter portion 13 and the ventilation portion 12a of the first shutter portion 12 overlap each other, so that the first shutter portion. When the 12 ventilation parts 12a are closed by the shielding piece 13b of the second shutter part 13, the heat insulation effect is improved by the shielding part 12b of the first shutter part 12 and the shielding piece 13b of the second shutter part 13 having good heat insulation properties. Can be made. Further, at that time, the indoor side warm air even if the outdoor temperature is low due to the shielding part 12b of the first shutter part 12 and the shielding piece 13b of the second shutter part 13 having good heat insulation properties. Can be prevented from being cooled in the vicinity of the first shutter portion 12 and the second shutter portion 13, so that dew condensation can be suppressed.

  In the present embodiment, the thermo element 24 is provided in the rotating device 14, and the linear movement operation along the piston portion 32 of the cylinder portion 31 according to the expansion and contraction of the temperature-sensitive member of the thermo element 24 is performed as the interlocking member. In the thermo element 24, the second shutter portion 13 is rotated by converting it into a rotation operation around the central axis (rotation shaft 23) of the exterior body 11 by the operation transmission unit 25 including the rotation member 35 and the rotation member 36. Unlike the coil spring made of shape memory alloy, since a large force for moving the cylinder portion 31 can be generated by utilizing the expansion of the temperature sensitive member made of wax or the like, the frictional force applied to the second shutter portion 13 is large. Or when a large force is required to rotate the second shutter unit 13 due to the size of the second shutter unit 13 being large or the like. The shutter unit 13 can be rotated.

  In the present embodiment, the interlocking member 35 and the rotating member 36 are connected via the operating shaft 36e at a position in the vicinity of the central axis (rotating shaft 23) in the radial direction of the exterior body 11, thereby connecting the interlocking member. Unlike the case where 35 and the rotating member 36 are connected at a position far from the central axis (the rotating shaft 23) in the radial direction of the exterior body 11, the cylinder portion 31 and the interlocking member 35 of the thermo element 24 move only slightly. In addition, the rotation distance of the rotation member 36 can be increased. As a result, even if the cylinder portion 31 and the interlocking member 35 of the thermo element 24 move only a little due to a slight change in temperature, the rotating member 36 and the second shutter portion 13 are made to react well to the change. The ventilation portion 12a of the first shutter portion 12 can be opened and closed by the shielding piece 13b of the second shutter portion 13 by being pivoted greatly.

  In the present embodiment, a common member can be used as the first shutter unit 12 and the second shutter unit 13 by forming the first shutter unit 12 and the second shutter unit 13 in the same shape. Thereby, compared with the case where the 1st shutter part 12 and the 2nd shutter part 13 are formed separately, the manufacturing process of the automatic shutter apparatus 1 can be simplified.

  Further, in the present embodiment, since the manual shutter device 3 having the ventilation window 44 that can be manually opened and closed is provided on the indoor side of the automatic shutter device 1 in the ventilation device, the thermal insulation by the automatic shutter device 1 is performed when the temperature is low. In addition to the effect, it is possible to obtain a further heat insulating effect by manually closing the ventilation window 44 of the manual shutter device 1.

  In the present embodiment, the manual shutter device 3 is detachably attached to the frame 2 fixed to the vent hole 510, and the automatic shutter device 1 is fixed to the manual shutter device 3 without being fixed to the frame 2. Therefore, even when the manual shutter device 3 is provided on the indoor side of the automatic shutter device 1, the automatic shutter device 1 and the manual shutter device 3 are integrated into the frame body 2 fixed to the vent hole 510. Can be removed indoors. That is, even when the manual shutter device 3 is provided on the indoor side of the automatic shutter device 1, only the operation of removing the manual shutter device 3 from the frame body 2 without performing the operation of removing the automatic shutter device 1 from the frame body 2. The automatic shutter device 1 can be easily removed indoors for maintenance.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and further includes meanings equivalent to the scope of claims for patent and all modifications within the scope.

  For example, in the above embodiment, the projecting portions 12g and 13g of the first shutter portion 12 and the second shutter portion 13 are both arranged on the outdoor side, but the present invention is not limited to this, and FIG. Like the automatic shutter device 61 shown in FIG. 22, the installation surface of the projection 12 g of the first shutter unit 12 and the second shutter unit are arranged on the indoor side by arranging the installation surface of the projection 12 g of the first shutter unit 12. You may make it the installation surface of 13 protrusion parts 13g oppose. With this configuration, when the temperature is low, the shielding piece 13b of the second shutter portion 13 is rotated so as to overlap the ventilation portion 12a of the first shutter portion 12, and the protruding portion 12g of the first shutter portion 12 is provided. When the forming region overlaps with the forming region of the protruding portion 13g of the second shutter portion 13, the opposing surfaces of the protruding portion 12g and the protruding portion 13g can be brought into contact with each other. Thereby, since the clearance gap between the 1st shutter part 12 and the 2nd shutter part 13 can be eliminated, ventilation | gas_flowing can be interrupted | blocked more. Thereby, the heat insulation effect when temperature is low can be improved more.

Moreover, in the said embodiment, although the thermo element 24 was used as a drive source for rotating the 2nd shutter part 13, as a reference example , using drive sources other than the thermo element 24, according to the high and low temperature The second shutter part 13 may be rotated. As a reference example, for example, a coil spring made of a shape memory alloy may be used as a drive source, and the second shutter unit 13 may be rotated according to the temperature.

  Moreover, in the said embodiment, although the 2nd shutter part 13 was provided in the outdoor side of the 1st shutter part 12, this invention is not restricted to this, The 2nd shutter part 13 is provided in the indoor side of the 1st shutter part 12. May be.

  Moreover, in the said embodiment, although the manual shutter apparatus 3 was provided in the indoor side of the automatic shutter apparatus 1, this invention is not restricted to this, You may provide the manual shutter apparatus 3 in the outdoor side of the automatic shutter apparatus 1. FIG.

It is the disassembled perspective view which showed the structure of the ventilation apparatus by one Embodiment of this invention. It is sectional drawing which showed the state which installed the ventilation apparatus by one Embodiment shown in FIG. 1 in the vent hole. It is a perspective view of the automatic shutter apparatus used for the ventilation apparatus by one Embodiment shown in FIG. It is a front view of the automatic shutter apparatus used for the ventilation apparatus by one Embodiment shown in FIG. It is a front view of the automatic shutter apparatus used for the ventilation apparatus by one Embodiment shown in FIG. FIG. 6 is a cross-sectional view of the automatic shutter device shown in FIG. 5 taken along line 100-100. It is sectional drawing along the 200-200 line | wire of the automatic shutter apparatus shown in FIG. It is a side view of the automatic shutter apparatus used for the ventilation apparatus by one Embodiment shown in FIG. It is sectional drawing along the 300-300 line | wire of the automatic shutter apparatus shown in FIG. It is sectional drawing along the 300-300 line | wire of the automatic shutter apparatus shown in FIG. It is a front view of the 1st shutter part and 2nd shutter part by one Embodiment of this invention. It is the side view seen from 400 directions of the 1st shutter part and 2nd shutter part which were shown in FIG. It is a front view of the housing by one Embodiment of this invention. It is a side view of the housing shown in FIG. It is a figure for demonstrating the attachment structure of the thermo element with respect to the housing shown in FIG. 13, and an interlocking member. It is a figure for demonstrating the attachment structure of the thermo element with respect to the housing shown in FIG. 13, and an interlocking member. It is a perspective view of the interlocking member by one Embodiment of this invention. It is the perspective view which looked at the interlocking member shown in Drawing 17 from the other direction. It is a side view of the rotation member by one Embodiment of this invention. It is the top view which looked at the rotation member shown in FIG. 19 from the outdoor side. It is a front view of the automatic shutter apparatus by the modification of one Embodiment of this invention. It is sectional drawing along the 500-500 line | wire of the automatic shutter apparatus by the modification shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Automatic shutter apparatus 2 Frame 2a Cylindrical part 3 Manual shutter apparatus 11 Exterior body 12 1st shutter part 12a Ventilation part 12b Shielding part 13 Second shutter part 13b Shielding piece 14 Rotating device 24 Thermo element 25 Operation transmitting part 31 Cylinder part 32 Piston part 35 Interlocking member (interlocking part)
36 Rotating member (Rotating part)
44 Ventilation window 510 Ventilation hole 500 Outer wall

Claims (6)

A substantially cylindrical exterior body installed so as to extend along the penetration direction in the ventilation hole penetrating the outer wall between the indoor and the exterior of the building;
Opened ventilation portions that are fixed in the exterior body and for taking ventilation between the inside and outside, and shielding portions that block ventilation are alternately arranged around the central axis of the exterior body along the circumferential direction of the exterior body. A formed first shutter portion;
In order to block the ventilation provided around the central axis adjacent to the indoor side or the outdoor side of the first shutter portion in the exterior body and arranged at a predetermined interval along the rotation direction A second shutter portion having a shielding piece of
It is provided so as to be located on the opposite side to the first shutter part with respect to the second shutter part in the exterior body, and when the air temperature is higher than a predetermined temperature, the second shutter part is arranged with the shielding piece and the first shutter. While the shutter part is rotated in the direction in which the shielding part overlaps, when the temperature is lower than the predetermined temperature, the second shutter part is rotated in the direction in which the shielding piece and the ventilation part of the first shutter part overlap. A rotating device to be
Both the shielding part of the first shutter part and the shielding piece of the second shutter part are formed of a heat insulating material ,
The rotating device is installed in the exterior body and has a housing in which a housing chamber that opens to the opposite side to the second shutter portion in the indoor / outdoor direction is formed, and the opposite side of the housing chamber to the second shutter portion. A housing cover that is attached to the housing so as to cover the opening of the cylinder, a cylinder part, a piston part that is attached to the cylinder part so as to be able to advance and retreat, and a temperature sensitive that is accommodated in the cylinder part and that expands and contracts depending on the temperature. A thermo element having a member, an interlocking portion that is housed in the housing chamber and linearly moves in a direction substantially perpendicular to the central axis together with the cylinder portion, and the second shutter portion, and is attached to the second shutter portion. A rotation unit that rotates about the central axis together with the shutter unit,
The interlocking portion has an elongated hole extending in a direction substantially perpendicular to the central axis and perpendicular to the moving direction of the interlocking portion,
The rotating portion is inserted into the elongated hole so as to be freely movable, and the elongated portion moves through the elongated hole while moving with the interlocking portion as the interlocking portion moves linearly with the cylinder portion. An automatic shutter device having an operation shaft for converting a linear movement operation of the interlocking portion into a rotation operation around the central axis of the rotation portion by moving along a direction in which the rotation portion extends . When air temperature is higher than the predetermined temperature, in the thermo-element, the cylinder portion is moved linearly in the direction in which the protruding amount from the cylinder portion of the piston portion is increased according to the expansion of the temperature sensitive member together by being heat us the movement is converted into rotational motion about the central axis to the rotator from the interlocking portion, the second shutter portion, the shielding piece and said first shutter portion While being rotated in the direction of overlapping with the shielding part,
When the temperature is lower than the predetermined temperature, in the thermo element, the cylinder portion linearly moves in a direction in which the amount of protrusion of the piston portion from the cylinder portion decreases according to the contraction of the temperature sensing member. by its movement is transfer us is converted into rotational motion about the central axis to the rotator from the interlocking portion, the second shutter portion, and the shielding piece of the first shutter portion The automatic shutter device according to claim 1, wherein the automatic shutter device is rotated in a direction in which the ventilation portion overlaps. Wherein A interlocking portion and the rotating portion, wherein the actuating shaft at a position near the central axis in the radial direction of the outer body are connected by being inserted into the elongated hole, to claim 1 or 2 The automatic shutter device described. The first shutter part and the second shutter part are formed in substantially the same shape,
Both the shielding part of the first shutter part and the shielding piece of the second shutter part are formed in a substantially fan shape so as to extend from the central axis side to the outside in the radial direction of the exterior body, and the ventilation of the first shutter part The automatic shutter device according to any one of claims 1 to 3 , wherein the portion is formed by a space between the shielding portions adjacent to each other along a circumferential direction of the exterior body. A ventilation device comprising the automatic shutter device according to any one of claims 1 to 4 ,
A ventilation device further comprising a manual shutter device provided on an indoor side or an outdoor side of the automatic shutter device and having a ventilation window that can be manually opened and closed. A frame that is fixed to the vent and has a cylindrical portion that houses the automatic shutter device;
The manual shutter device is detachably attached to the frame,
The ventilation device according to claim 5 , wherein the automatic shutter device is fixed to the manual shutter device without being fixed to the frame.

Images