JP5757593B2 - Blind drive - Google Patents

Description

  The present invention relates to a blind driving apparatus for driving a blind.

  There is known a technique in which a plurality of window glasses are arranged apart from each other inside and outside the sash frame, and blinds are arranged in a space defined between these window glasses (see Patent Document 1). In such a blind, the shielding material is supported by the sash frame, and the shielding material is driven to open and close by a driving device provided on one side frame of the sash frame supporting the shielding material. . This driving device is provided on one side frame so as to protrude indoors, and is provided with a tilt operation dial for operating the opening / closing drive of the shielding material, and is provided inside one side frame to shield the operation of the tilt operation dial. And a mechanism including a drive shaft, a pinion, a rack, a transmission cord, and the like that are transmitted to the material.

JP 2010-222924 A JP 2005-344484 A

  By the way, the drive device provided in such a sash frame is provided in the sash frame of the sash in which the shielding material is provided. For this reason, the tilt operation dial for opening and closing the shielding member provided on the outdoor sash needs to be provided in a portion not overlapping with the indoor sash frame when the sash is closed. Therefore, the tilt operation dial must be provided at a position that does not overlap with the sash frame on the indoor side, and is thus provided so as to protrude toward the opening of the sash. For this reason, the width of the opening of the outdoor sash is narrowed, and as a result, the area of the opening is narrowed.

  By the way, if an operation unit such as a tilt operation dial for operating the opening / closing of the shielding material is not provided in the sash where the shielding material is provided, but is provided detachably with respect to the blind (see Patent Document 2). The area of the opening can be increased. Even in such a configuration, the operation unit and the mechanism for opening and closing the shielding material are connected, whereby the operation of the operation unit is transmitted to the mechanism and the shielding material is opened and closed. In this case, when the operating unit is once removed from the blind and reattached, the operating position of the operating unit and the operating position of the mechanism are not maintained, and the operating unit is reattached. The power is transmitted while the operation positions are shifted from each other. However, there is a possibility that the operation position of the operation unit removed from the blind may be changed by touching something. Therefore, the operation unit and the mechanism are not necessarily connected in the state when removed. For this reason, there is a problem that power may be transmitted while the operating position of the operation unit and the operating position of the mechanism are deviated, and the blind may not be driven normally.

  Therefore, the present invention has been made in view of such problems, and the object of the present invention is to drive the blinds normally even if the operation unit and the mechanism for driving the blinds are detachable. In addition, a blind driving device is provided in which the area of the opening of the sash supporting the shielding material can be increased by applying a configuration in which the operation unit and the mechanism for driving the blind are detachable to the sash. There is.

  In order to solve the above-described problem, according to the present invention, a sash set including a first sash provided on the indoor side and a second sash provided on the outdoor side and provided with a blind is provided. A blind drive device for driving a blind, comprising: an operation unit provided in a first sash; a drive unit provided in the first sash and driven by operation of the operation unit; and a second sash And a driven portion for driving the blind by transmitting power by being coupled to the drive portion of the first sash in the closed state of the sash set. Is provided.

  According to this invention, the drive device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, and is operated on the first indoor sash. By providing the portion, the operation portion can be exposed to the indoor side regardless of the open / closed state of the sash set, and there is no need to narrow the opening of the second sash. Therefore, the area of the opening of the first and second sashes can be increased.

  The drive unit includes a drive shaft, the driven unit includes a driven shaft, and at least one of the drive shaft and the driven shaft is a surface of the first sash and the second sash facing each other by the biasing means. The drive shaft and the driven shaft are both rotatable around the shaft, and the drive shaft and the driven shaft have engaging portions that engage with each other. The drive shaft and the driven shaft may be integrally rotated by engaging each other's engaging portions. Thus, since the drive shaft and the driven shaft rotate integrally by the engagement of the engaging portions, the rotation of the drive shaft can be reliably transmitted to the driven shaft. As a result, even if the driving device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, the driving device is provided in the first indoor sash. The operation of the operation unit can be reliably transmitted to the blind provided in the second sash on the outdoor side.

  Furthermore, the drive shaft and the driven shaft may be pressed in the axial direction to a position where one shaft cannot engage the other shaft when the engaging portions are not engaged with each other. . Thereby, for example, when the sash set is opened, the operation unit is erroneously operated, the drive shaft rotates, and the positions of the engaging portions of the drive shaft and the driven shaft are shifted. When closed, one shaft presses while the other shaft cannot engage each other. For this reason, since the engaging parts of a drive shaft and a driven part do not engage, even if an operation part is operated, motive power is not transmitted from a drive shaft to a driven shaft, and an erroneous operation can be prevented. As a result, even if the driving device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, the driving device is provided in the first indoor sash. Thus, the power generated by the operation of the operation unit is prevented from being transmitted to the blind provided in the second sash on the outdoor side in an incorrect positional relationship.

  Further, the drive shaft and the driven shaft may rotate relatively until the engaging portions engage with each other. For this reason, the engaging portion of the driven shaft does not engage with the engaging portion of the driven shaft until the engaging portion of the driving shaft returns to the normal position. Therefore, the position of the operating portion is reset, and the driving shaft and the driven shaft are in a normal positional relationship. Can be returned. As a result, even if the driving device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, the driving device is provided in the first indoor sash. The operating unit and the driving unit and the driven unit provided in the second sash on the outdoor side can always be operated in a normal positional relationship.

  Here, the drive shaft is always urged by the first urging means, and the driven shaft is arranged so that the tip of the driven shaft is flush with the indoor surface of the second sash by the second urging means. The urging force of the second urging unit may be set to be smaller than the urging force of the first urging unit. Thereby, when the drive shaft and the driven shaft are separated, such as when the sash set is opened, the interior side surface of the second sash is blocked by the tip of the driven shaft. It is possible to prevent foreign matters from entering the second sash. As a result, even if the driving device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, the failure of the driving device due to intrusion of foreign matter or the like can be prevented. Can be prevented.

  According to the present invention, there is also provided a blind driving device for driving a blind attached to a window frame, the operating device being detachably attached to the blind, and operating the blind drive, and the blind. A drive unit that is driven by operation of the operation unit, and a driven unit that is provided on the blind and that is driven by the drive unit to transmit power by being coupled to the drive unit, The driven portion includes an engaging portion that engages with each other, and a drive device for a blind is provided in which power is transmitted when the engaging portions engage with each other.

  According to this invention, for example, in order to change the operation position on the left and right of the blind, even if the position of the engagement portion of the drive unit is changed after the operation unit and the drive unit are once removed from the blind, the drive unit and Since the driven portion is a structure in which power is transmitted by the engagement of the engaging portions with each other, the drive portion always engages the driven portion at the position of the engaging portion when removed. become. For this reason, it is possible to prevent power from being transmitted while the positions of the drive unit and the driven unit are shifted. Thereby, even if the drive device for driving the blind is divided into a blind and a separate part from the blind, the blind can always be driven normally.

  In addition, for example, when an operation pulley is used for the operation unit and the drive unit and a rotation shaft is used for the driven unit, the connector of the operation chain is changed when the relationship between the rotation position of the operation pulley and the rotation position of the rotation shaft changes. Operation failure may occur, such as being trapped in and being unable to operate. However, according to the above-described mechanism, since the rotation position of the operation pulley and the rotation position of the rotation shaft are connected without being changed, it is possible to prevent operation failure.

  Further, in the case of an electric blind, by providing an engaging portion that engages with a shaft of a motor that is a driving portion and a rotating shaft that is a driven portion, the electric blind can be used for positioning.

According to the present invention, the drive device for driving the blind is divided into the second outdoor sash provided with the blind and the first indoor sash, and is operated on the first indoor sash. By providing the portion, it is not necessary to narrow the opening of the second sash in order to expose the operation portion to the indoor side. Therefore, the area of the opening of the first and second sashes can be increased.
The other effects of the present invention will be described in the section for carrying out the invention below.

It is a front view of the sash set which implemented the drive device of the blind concerning a 1st embodiment of the present invention. It is a fragmentary perspective view which shows the state which open | released the 1st sash and the 2nd sash. FIG. 5 is a side sectional view of the vicinity of the opened first and second sash drive devices. It is sectional drawing of the drive device vicinity of the open | released 1st sash and 2nd sash. It is a figure explaining the flow of operation | movement of 1st Embodiment, (a) is a sectional side view which shows the state in which the 1st sash and the 2nd sash were open | released, (b) is (a) ) Is a cross-sectional view taken along the line B-B of FIG. It is a figure explaining the flow of operation | movement of 1st Embodiment, (a) is a sectional side view which shows the state with which the 1st sash and the 2nd sash were closed, (b) is ( It is CC sectional drawing of a). It is a figure explaining the flow of operation | movement of 1st Embodiment, (a) is a sectional side view which shows the state which closed the slat, (b) is DD sectional drawing of (a). . It is a figure explaining the flow of operation of a 1st embodiment, and (a) is a sectional side view showing the state where a sash was closed in the state where the positions of the engaging parts of a drive shaft and a driven shaft do not correspond. (B) is an EE cross-sectional view of (a). It is sectional drawing which shows the state which open | released the 1st sash and the 2nd sash. It is sectional drawing which shows the state which closed the 1st sash and the 2nd sash. It is sectional drawing which shows the state which closed the 1st sash and the 2nd sash and operated the operation part. It is a schematic diagram which shows transmission of the driving force when a slat is a horizontal state. It is a schematic diagram which shows transmission of the driving force when a slat is a closed state. It is a perspective view of the drive device of 2nd Embodiment. It is a perspective view of the drive device of 3rd Embodiment.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

(First embodiment)
A blind driving apparatus according to a first embodiment will be described with reference to FIGS.
First, the configuration of the blind drive device according to the present embodiment will be described. As shown in FIG. 1, the driving device 100 includes a first sash 200 provided on the indoor side of a window opening of a building (not shown), and a second sash 300 disposed on the outdoor side of the window opening. And the blind 400 provided in the second sash 300 is driven. In the present embodiment, the first sash 200 and the second sash 300 constitute a one-sided window. Hereinafter, each configuration will be described in detail.

(First sash 200)
As shown in FIGS. 1 and 2, the first sash 200 is composed of only a frame in which glass or the like is not fitted, and is fixed to a window opening of a building not shown. In the lower frame 210 of the first sash 200, an operation unit 110 and a drive unit 120, which will be described later, of the drive device 100 are disposed. A first opening 211 extending in the longitudinal direction is formed on the surface of the lower frame 210 on the indoor side, and an operation knob 113 (to be described later) of the driving device 100 protrudes into the room through the first opening 211. Further, a substantially inverted U-shaped second opening 212 is formed on the outdoor side surface of the lower frame 210, and a drive unit case 121, which will be described later, of the drive device 100 is formed through the second opening 212. The tip of the cylindrical support part 121a protrudes.

(Second sash 300)
As shown in FIGS. 1 and 2, the second sash 300 is provided with glass 320 and 330 spaced apart from each other on the indoor side and the outdoor side of the rectangular frame 310. A sealed space 340 is formed by the frame 310, the indoor-side glass 320, and the outdoor-side glass 330. Further, in the second sash 300, the right side frame 311 in FIG. 2 is connected to the side frame of the first sash 200, and the second sash 300 swings in the outdoor direction around the right side frame 311. It has become. In the sealed space 340 of the second sash 300, a blind 400 and a driven unit 130 (to be described later) of the driving device 100 are provided. A cylindrical third opening 312a is formed in the lower frame 312 of the second sash 300, and a distal end portion of a driven portion case 131 (to be described later) of the driving device 100 is fitted.

  The first sash 200 and the second sash 300 are configured such that the lower frame 210 and the lower frame 312 overlap each other when they are closed.

(Blind 400)
As shown in FIG. 1, the blind 400 is provided in the sealed space 340 of the second sash 300. The blind 400 winds and unwinds the upper end of the ladder cord 410 in a head box disposed in the upper frame 313 of the second sash 300 and a large number of slats 420 supported in alignment by the ladder cord 410. A rotating drum 430 that supports the rotation (note that the rotating drum 430 only appears in one place in FIG. 1) and a rotation that extends over the entire length of the head box in the longitudinal direction and penetrates the rotating drum 430 so as to rotate integrally. And a shaft 440.

  In the blind 400, the rotating drum 430 rotates integrally with the rotation of the rotating shaft 440, and the rotating drum 430 winds up one of the ladder cords 410 that hangs forward and backward of the slat 420 and unwinds the other. The slat 420 is rotated. Thereby, the slat 420 opens and closes.

(Drive device 100)
As shown in FIGS. 1 and 2, the driving device 100 is provided in the operation unit 110 provided in the first sash 200, the driving unit 120 provided in the first sash 200, and the second sash 300. And a follower 130. The drive unit 120 is driven by the operation of the operation unit 110. In the state where the first sash 200 and the second sash 300 are closed, the driven unit 130 is connected to the driving unit 120 of the first sash 200 to transmit power to open and close the slat 420. . Hereinafter, each structure of the drive device 100 will be described in detail.

(Operation unit 110)
As shown in FIGS. 3 and 4, the operation unit 110 is provided in the lower frame 210 of the first sash 200 so as to slide in the longitudinal direction, and extends to the bottom 111 a and the side extending in the longitudinal direction of the lower frame 210. A sliding portion 111 having a substantially L-shaped cross section composed of a portion 111b, a rack 112 provided on the upper surface of the bottom portion 111a so as to extend in the longitudinal direction, and an operation knob 113 protruding from the side portion 111b. The The sliding portion 111 is disposed such that the bottom portion 111 a is positioned on the bottom surface side of the lower frame 210 and the side portion 111 b is positioned on the side surface side of the lower frame 210 on the indoor side. Further, as described above, the operation knob 113 protrudes indoors through the first opening 211 provided on the indoor side surface of the lower frame 210. Accordingly, an operator in the room slides the operation knob 113 in the longitudinal direction of the lower frame 210, so that the sliding portion 111 slides in the longitudinal direction of the lower frame 210 together with the operation knob 113.

(Driver 120)
As shown in FIGS. 3 and 4, the drive unit 120 is rotatably supported by the drive unit case 121 fixed to the lower frame 210 of the first sash 200 and the drive unit case 121, and the tip is lowered. A drive shaft 122 that protrudes from the frame 210 to the outside, and a first spring (first urging means) 123 that constantly urges the drive shaft 122 in the direction that protrudes to the outside of the frame 210 are configured. Hereinafter, each component of the drive unit 120 will be described in detail.

(Driver case 121)
As shown in FIGS. 3 and 4, the drive unit case 121 is fixed in the lower frame 210, and includes a cylindrical support portion 121 a that protrudes outside the second opening 212 of the lower frame 210. ing. The cylindrical support part 121a has a shoulder part 121a-3 at the front part 121a-2 which is a part protruding outside the rear part 121a-1 which is a part arranged in the lower frame 210. It has a small diameter. A drive shaft 122 is inserted into the cylindrical support 121a so as to be rotatable and slidable in the axial direction.

(Drive shaft 122)
As shown in FIGS. 3 and 4, the drive shaft 122 is slidable in the axial direction on the cylindrical support 121a and is rotatably supported by the rotary support 122a, and the cylindrical support 121a. And a rotating part 122b supported rotatably. The rotary sliding part 122a and the rotary part 122b are configured to rotate integrally and relatively move in the axial direction.

  As shown in FIG. 2, a first engagement portion 122a-1 protruding in the radial direction is formed at a part of the circumferential direction at the tip of the rotary sliding portion 122a, and a diameter at the rear end. A flange portion 122a-2 protruding in the direction is formed on the entire circumference in the circumferential direction. The collar portion 122a-2 protrudes from the cylindrical support portion 121a of the rotary sliding portion 122a by contacting the shoulder portion 121a-3 of the drive portion case 121 when the rotary sliding portion 122a slides. It restricts further sliding in the direction. The tip of the rotary sliding part 122a is a flat surface.

  A pinion 122b-1 having a diameter larger than that of the rear part 121a-1 of the cylindrical support part 121a is formed at the rear end of the rotating part 122b. The pinion 122b-1 includes a rear end part and an operation part of the cylindrical support part 121a. It is located between 110 side parts 111b, and the movement of an axial direction is restrained among these. The pinion 122b-1 meshes with the rack 112 of the operation unit 110, and when the rack 112 slides integrally with the operation unit 110, the pinion 122b-1 rotates and the drive shaft 122 rotates. ing.

(First spring 123)
As shown in FIGS. 3 and 4, the first spring 123 is disposed between the flange portion 122 a-2 of the rotary sliding portion 122 a and the pinion 122 b-1 of the rotary portion 122 b, and one end of the first spring 123 is a flange. The other end is connected to the portion 122a-2 and the pinion 122b-1. Thereby, the rotation sliding part 122a is always urged | biased in the direction which protrudes from the front-end | tip of the cylindrical support part 121a.

(Following part 130)
As shown in FIGS. 3 and 4, the driven unit 130 is supported by the driven unit case 131 fixed to the second sash 300 and the driven unit case 131 so as to be axially slidable and rotatable. Driven shaft 132, a second spring (second biasing means) 133 that constantly presses the driven shaft 132 toward the opening end of the driven portion case 131, and a transmission portion 134 that transmits the drive of the driven shaft 132 to the rotating shaft 440. And comprising.

(Following part case 131)
As shown in FIGS. 3 and 4, the follower case 131 is fixed to the lower frame 312 of the second sash 300, and includes a large-diameter portion 131 a disposed in the sealed space 340 and the lower frame 312. And a small-diameter portion 131b fitted into the third opening 312a. When the first sash 200 and the second sash 300 are closed and the lower frame 210 and the lower frame 312 overlap each other, the rotation sliding portion of the driving unit 120 is formed in the small-diameter portion 131b of the driven unit case 131. 122a is inserted.

(Driven shaft 132)
The driven shaft 132 includes a bottomed cylindrical rotating portion 132a that is rotatably supported by the driven portion case 131, and a sliding portion 132b that is slidably supported in the rotating portion 132a in the axial direction. It is configured.

  As shown in FIG. 2, the rotating portion 132 a has a second engagement portion 132 a-1 formed by notching a part of the opening end portion located on the indoor side in the circumferential direction. The first engagement portion 122a-1 of the drive shaft 122 described above is engaged with the second engagement portion 132a-1, and the drive shaft 122 and the driven shaft 132 rotate integrally. Moreover, the 1st pulley 132a-2 is formed in the edge part of the outdoor side of the rotation part 132a.

  The sliding portion 132b also has a bottomed cylindrical shape, and is inserted into the rotating portion 132a so as to be slidable in the axial direction. The bottom part of the sliding part 132b is arranged so as to be positioned on the opening end side of the rotating part 132a, whereby the opening end part of the rotating part 132a is closed by the bottom part of the sliding part 132b. Yes. The tip of the sliding part 132b is a flat surface, and when it comes into contact with the flat surface of the tip of the rotary sliding part 122a of the drive shaft 122, it rotates relative to each other without being engaged with each other.

(Second spring 133)
The second spring 133 is provided in a space defined by the rotating portion 132a and the sliding portion 132b. One end of the second spring 133 is at the bottom of the rotating portion 132a and the other end is the bottom of the sliding portion 132b. Respectively. When the second spring 133 has a natural length, the bottom portion of the sliding portion 132b is positioned at the opening end portion of the rotating portion 132a. The pressing force of the second spring 133 is set smaller than the pressing force of the first spring 123 of the drive unit 120.

(Transmission unit 134)
As shown in FIG. 1 and FIG. 4, the transmission unit 134 is respectively connected to the second pulley 134 a provided at the end of the rotating shaft 440, and the second pulley 134 a and the first pulley 132 a-2 of the driven unit 130. And an endless wire 134b wound around. After the wire 134b is wound around the second pulley 134a, the wire 134b descends in the left side frame 314 of the second sash 300, is bent at the lower end of the side frame 314, and is routed in the lower frame 312 to be routed. 1 pulley 132a-2 is wound around. Accordingly, when the first pulley 132a-2 of the driven unit 130 rotates, the second pulley 134a rotates through the wire 134b, and the rotating shaft 440 rotates together with the second pulley 134a.

Next, the operation of the present embodiment will be described with reference to FIGS. 5A to 5D and FIGS. 6A to 6C.
When the first sash 200 and the second sash 300 are open, as shown in FIGS. 5A (a) and 6A, the lower sash 200 and the second sash 300 are below The frame 312 is separated. Thereby, the drive unit 120 and the driven unit 130 are separated from each other, and the power of the drive unit 120 is not transmitted to the driven unit 130. Further, the first engaging portion 122a-1 of the driving shaft 122 of the driving portion 120 and the second engaging portion 132a-1 of the driven shaft 132 of the driven portion 130 are shown in FIGS. 5B and 5C. As shown, it is located above as it is when separated from each other.

  In this state, in the driving unit 120, the rotating sliding portion 122a of the driving shaft 122 is pressed outward from the first sash 200 by the elastic force of the first spring 123, and the collar portion 122a-2 is moved to the shoulder portion 121a. -3 is in the most protruding state in contact with -3.

  On the other hand, in the driven portion 130, the second spring 133 has a natural length, and the sliding portion 132b of the driven shaft 132 protrudes most. For this reason, the opening end part of the rotation part 132a is obstruct | occluded by the bottom part of the sliding part 132b. As described above, when the first sash 200 and the second sash 300 are opened, the opening end of the rotating portion 132a is closed by the bottom of the sliding portion 132b. Foreign matter such as dust is prevented from entering.

  Next, when the first sash 200 and the second sash 300 are closed, as shown in FIG. 5B (a) and FIG. 6B, the lower frame 210 of the first sash 200 and the bottom of the second sash 300 are provided. The frame 312 overlaps. As a result, the position of the rotary sliding portion 122a of the drive shaft 122 matches the position of the sliding portion 132b of the driven shaft 132. At this time, as shown in FIG. 5B (b), the position of the first engagement portion 122a-1 of the rotation sliding portion 122a and the position of the second engagement portion 132a-1 of the rotation portion 132a coincide with each other. Since the pressing force of the second spring 133 pressing the sliding portion 132b is smaller than the pressing force of the first spring 123 pressing the rotating sliding portion 122a, the rotating sliding portion 122a is The sliding portion 132b is inserted into the driven portion case 131 and the rotating portion 132a while being pushed into the rotating portion 132a. As a result, the first engagement portion 122a-1 of the rotation sliding portion 122a and the second engagement portion 132a-1 of the rotation portion 132a are engaged, and therefore the rotation of the rotation sliding portion 122a of the drive shaft 122 is driven. The state is transmitted to the rotating portion 132a of the shaft 132.

  As described above, the blind 400 is driven in a state where the first engagement portion 122a-1 and the second engagement portion 132a-1 are engaged and the rotation of the rotation sliding portion 122a is transmitted to the rotation portion 132a. can do.

  Next, the operation when the blind 400 is driven will be described with reference to FIGS. 5B, 5C, 6B, 6C, 7A, and 7B.

  As shown in FIGS. 6B and 7A, when the slat 420 is in a horizontal state, the operation knob 113 is positioned at the center in the longitudinal direction of the first opening 211 of the lower frame 210, and the pinion 122b-1 is in the longitudinal direction of the rack 112. It is in a state of meshing at the center position. At this time, the first engaging portion 122a-1 of the rotating sliding portion 122a and the second engaging portion 132a-1 of the rotating portion 132a are located at the upper portion as shown in FIG. 5B (b). .

  Next, the operator slides the operation knob 113 from the room in the right direction indicated by the arrow A in FIGS. 6C and 7B of the first opening 211. As a result, the sliding portion 111 slides in the lower frame 210 in the right direction in the figure, so that the rack 112 slides and the rotating portion 122b is moved to the arrow B in FIG. 7B by the pinion 122b-1 meshing with the rack 112. Rotate in the direction. The rotation of the rotating part 122b is transmitted to the first pulley 132a-2 via the rotating / sliding part 122a and the rotating part 132a engaged with the rotating / sliding part 122a. Accordingly, since the first pulley 132a-2 rotates in the direction of arrow C in FIG. 7B, the rotary shaft 440 is rotationally driven together with the second pulley 134a via the wire 134b. Therefore, as described above, one of the ladder cords 410 is wound around the rotary drum 430 and the other is unwound, and the slats 420 are rotated and closed as shown in FIGS. 5C (a) and 7B. At this time, the first engagement portion 122a-1 of the rotation sliding portion 122a and the second engagement portion 132a-1 of the rotation portion 132a are positioned obliquely downward as shown in FIG. 5C (b). Yes.

  In order to return the slat 420 to the horizontal state again, the operator slides the operation knob 113 in the left direction in FIGS. 6C and 7B of the first opening 211, and as shown in FIG. The opening 211 is positioned at the center in the longitudinal direction. As a result, as shown in FIGS. 6B and 7A, the pinion 122b-1 is engaged at the longitudinal center position of the rack 112, and the slat 420 is in the horizontal state.

  Next, referring to FIG. 5D, when the first sash 200 and the second sash 300 are opened, the operation knob 113 is operated, and the rotary sliding portion 122a is rotated. A case where the first sash 200 and the second sash 300 are closed in the state will be described.

  In such a state, the operation knob 113 is located at a position shifted from the center in the longitudinal direction of the first opening 211, and the pinion 122 b-1 is also engaged at a position shifted from the center in the longitudinal direction of the rack 112.

  When the first sash 200 and the second sash 300 are closed in such a state, the lower frame 210 and the lower frame 312 overlap as shown in FIG. The position matches the position of the sliding part 132b. However, as shown in FIG. 5D (b), the position of the first engagement portion 122a-1 of the rotation sliding portion 122a and the position of the second engagement portion 132a-1 of the rotation portion 132a coincide with each other. Therefore, as shown in FIG. 5D (a), the rotary sliding portion 122a comes into contact with the end portion of the rotary portion 132a. As a result, the rotary sliding portion 122a slides in the backward direction against the elastic force of the first spring 123 and is accommodated in the cylindrical support portion 121a.

  Thus, even if the 1st sash 200 and the 2nd sash 300 are closed in the state where the position of the 1st engagement part 122a-1 and the 2nd engagement part 132a-1 has shifted, the 1st Since the engaging part 122a-1 and the second engaging part 132a-1 are not engaged, the rotation of the rotary sliding part 122a is not transmitted to the rotating part 132a. Further, as described above, the operation unit 110 also has the position of the operation knob 113 and the position of the rack 112 and the pinion 122b-1 shifted.

  Therefore, with the first sash 200 and the second sash 300 closed, the operator slides the operation knob 113 from the room to the center position in the longitudinal direction of the first opening 211. Thereby, since the sliding part 111 slides in the lower frame 210 in the longitudinal direction, the rack 112 slides integrally therewith, and the rotating part 122b and the rotating sliding part 122a rotate integrally by the pinion 122b-1. To do. When the first engagement portion 122a-1 rotates to a position that matches the second engagement portion 132a-1, the rotary sliding portion 122a protrudes from the cylindrical support portion 121a by the pressing force of the first spring 123. Slide in the direction. Thereby, the first engagement portion 122a-1 and the second engagement portion 132a-1 are engaged, and the rotation of the rotation sliding portion 122a is transmitted to the rotation portion 132a. The position of the operation knob 113 at this time is at the center in the longitudinal direction of the first opening 211 as described above, and the pinion 122b-1 is engaged at the center position in the longitudinal direction of the rack 112. Has returned to its normal position.

  Thus, the rotation sliding part 122a and the rotation part 132a rotate relatively until the engagement parts 122a-1 and 132a-1 are engaged with each other, and the first engagement of the rotation sliding part 122a. When the part 122a-1 returns to the normal position, the position of the operation part 110 is reset to engage with the second engaging part 132a-1 of the rotating part 132a, and the drive shaft 122 and the driven shaft 132 are brought into normal. It can be returned to the positional relationship.

  As described above, according to the present embodiment, the operation unit 110 for operating the driving of the blind 400 provided in the second sash 300 disposed on the outdoor side is the first sash 200 disposed on the indoor side. The lower frame 312 of the second sash 300 and the lower frame 210 of the first sash 200 overlap each other so that the operation of the operation unit 110 is transmitted to the blind 400. Therefore, in order to expose the operation unit 110 to the indoor side with the first sash 200 and the second sash 300 closed, an operation is performed on a portion of the second sash 300 that does not overlap the first sash 200. There is no need to arrange the portion 110. Therefore, since it is not necessary to narrow the opening of the second sash 300, the area of the opening of the second sash 300 can be increased.

  In addition, the transmission of power between the drive shaft 122 and the driven shaft 132 is performed by engaging the engaging portions 122a-1 and 132a-1 with each other, so that the power can be reliably transmitted.

  Further, for example, when the first sash 200 and the second sash 300 are opened, the operation knob 113 is erroneously operated to rotate the drive shaft 122, and the engagement portion 122a- of the drive shaft 122 and the rotation portion 132a is rotated. When the positions of the first and second 132a-1 are shifted, the first engaging portion 122a-1 of the rotary sliding portion 122a is not rotated even if the first sash 200 and the second sash 300 are closed. Is brought into a state of being accommodated in the cylindrical support portion 121a. For this reason, the drive shaft 122 and the engaging portions 122a-1 and 132a-1 of the rotating portion 132a are not engaged with each other. Thereby, even if the operation knob 113 is operated, power is not transmitted from the drive shaft 122 to the driven shaft 132, so that an erroneous operation can be prevented.

  Further, until the first engagement portion 122a-1 of the drive shaft 122 returns to the normal position, the position of the operation portion 110 is reset because it does not engage with the second engagement portion 132a-1 of the driven shaft 132. The drive shaft 122 and the driven shaft 132 can be returned to a normal positional relationship.

  Furthermore, when the driving unit 120 and the driven unit 130 are separated, such as when the first sash 200 and the second sash 300 are opened, the opening end of the rotating unit 132a is It is closed by the bottom of the sliding part 132b pressed by the two springs 133. For this reason, it is possible to prevent foreign matters such as dust and dust from entering the driven portion case 131.

  In the present embodiment, the driving device 100 is provided on the lower frame 210 of the first sash 200 and the lower frame 312 of the second sash 200, but may be provided on the side frames of the respective sashes 110 and 120. .

  Alternatively, the first sash 200 and the second sash 300 may be used as a sliding sash, and the blinds 400 may be disposed on both sashes 200 and 300, respectively. Thus, the driving device 100 of the present embodiment is provided in the overlapping frame of the first sash 200 and the second sash 300, and the driving of the blind 400 of the second sash 300 on the outdoor side is performed on the first sash on the indoor side. The operation unit 110 provided in 200 may be operated.

(Second Embodiment)
A driving apparatus 100 according to the second embodiment will be described with reference to FIG. The drive device 100 according to the present embodiment does not drive the blind provided in the sash as in the first embodiment, but drives a normal blind attached to the window frame. That is, the drive device 100 according to the present embodiment is provided in a head box (not shown) fixed to the window frame, and drives a slat supported by the head box. Details of the drive device 100 according to the present embodiment will be described below, but redundant description of the same parts as those of the first embodiment will be omitted.

  As in the first embodiment, the driving device 100 is connected to the operation unit 110, the drive unit 120 driven by the operation of the operation unit 110, and the drive unit 120 to transmit power to drive the blind. And a driven portion 130 configured to be configured. However, unlike the first embodiment, the transmission unit 134 is not provided, and the driven unit 130 is directly provided on the rotating shaft 440. Hereinafter, each structure of the operating device 100 will be described in detail.

(Operation unit 110)
The operation unit 110 includes an operation pulley 115 corresponding to the sliding unit 111 and the rack 112 of the first embodiment, and an operation chain 116 wound around the operation pulley 115 and corresponding to the operation knob 113 of the first embodiment. It is comprised by. By operating the operation chain 116, the operation pulley 115 is rotationally driven.

(Driver 120)
The drive unit 120 is configured such that the drive case 121 protrudes in the direction of the rotation axis from one surface of the operation pulley 115, and is connected so that a rotation unit 122 b (not shown) of the drive shaft 122 rotates integrally with the operation pulley 115. ing. Other configurations are the same as those of the first embodiment.

(Following part 130)
The follower 130 is configured to be directly attached to one end of the rotating shaft 440 disposed in the head box as described above, and as shown in FIG. 8, the follower case 131 having a cylindrical shape. And the rotating portion 132a of the driven shaft 132 are coupled to rotate integrally with the rotating shaft 440. Other configurations are the same as those of the first embodiment.

  Similarly to the first embodiment, when the position of the first engagement part 122a-1 and the position of the second engagement part 132a-1 do not coincide with each other, the drive unit 120 and the driven part 130 are driven by the drive shaft 122. And the driven shaft 132 are not rotated and connected to each other, so that the rotation of the drive shaft 122 is not transmitted to the driven shaft 132. On the other hand, the drive shaft 122 and the driven shaft 132 are connected only when the position of the first engagement portion 122a-1 and the position of the second engagement portion 132a-1 coincide with each other. Power is transmitted. As a result, the rotational position of the drive shaft 122 of the drive unit 120 can be coupled with the rotational position of the driven shaft 132 of the driven unit 132. Therefore, the connector of the operation chain 116 wound around the operation pulley 115 is generated by the change in the rotation position of the drive shaft 122 and the rotation position of the driven shaft 132, and the operation pulley 115 is not operated. Can be prevented.

  In addition, since the drive unit 120 and the driven unit 130 can always be connected in an appropriate state, when the drive unit 120 is once removed and attached to the driven unit 130 again, or when the drive unit 120 or the operation unit 110 breaks down. In addition, it becomes easy to change to a new one. Further, by providing the driven portions 130 at the left and right end portions of the head box, the driving portion 120 and the operation portion 110 can be arbitrarily attached to either end portion of the head box.

(Third embodiment)
A driving apparatus 100 according to a third embodiment will be described with reference to FIG. The drive device 100 according to the present embodiment is obtained by changing the shape of the drive unit case 121 to the electric motor 117 as the entire operation unit 110 of the drive device 100 of the second embodiment, and the other parts are the second. This is the same as the embodiment. Details of the drive device 100 according to the present embodiment will be described below, but redundant description of the same parts as those of the second embodiment will be omitted.

  An output shaft (not shown) of the electric motor 117 is connected to a rotating portion 122b (not shown) constituting the driving shaft 122 of the driving portion 120 so as to rotate integrally therewith, whereby the driving shaft 122 is driven by the driving of the electric motor 117. Rotates.

  The connection between the drive unit 120 and the driven unit 130 of the present embodiment is performed in the same manner as in the second embodiment, and the position of the first engagement unit 122a-1 and the position of the second engagement unit 132a-1 coincide. Since the coupling is performed only in the state, the coupling can be performed in a state where the rotational position of the drive shaft 122 and the rotational position of the driven shaft 132 are matched.

  In addition, since the drive unit 120 of the present embodiment is also detachable from the driven unit 130, the drive unit 120 and the motor 117 can be replaced or either of the both ends of the head box, as in the second embodiment. Can be installed arbitrarily.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to this example. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. is there.

  In each of the above embodiments, the driving device 100 is configured to rotate the slat 420, but the slat 420 may be moved up and down, or both rotated and lifted. In addition, although the Venetian blind is illustrated as the blind 400, it is needless to say that the blind 400 can be applied to a vertical blind, a roll screen, a pleated screen, a scooping curtain, and the like. It is good also as what opens and closes a shielding material.

DESCRIPTION OF SYMBOLS 100 Drive apparatus 110 Operation part 120 Drive part 122 Drive shaft 122a-1 1st engaging part 123 1st spring (1st biasing means)
130 driven portion 132 driven shaft 132a-1 second engaging portion 133 second spring (second urging means)
200 First sash 300 Second sash 400 Blind

Claims (6)

In order to drive the blind provided in a sash set comprising a first sash (200) provided on the indoor side and a second sash (300) provided on the outdoor side and provided with a blind (400). The blind drive device (100),
An operation unit (110) provided in the first sash;
A drive unit (120) provided in the first sash and driven by operation of the operation unit;
Provided in the second sash, in the closed state of the sash set, the sash set is connected to the driving portion of the first sash to transmit power to drive the blind, and the sash set is opened. A driven part (130) for releasing the connection ;
A blind drive device comprising: The driving unit includes a driving shaft (122), and the driven unit includes a driven shaft (132).
At least one of the drive shaft and the driven shaft protrudes from the opposing surfaces of the first sash and the second sash by the biasing means (123, 133) and slides in the axial direction. And both the drive shaft and the driven shaft are rotatable about an axis,
The drive shaft and the driven shaft are respectively provided with engaging portions (122a-1, 132a-1) that engage with each other,
2. The blind driving device according to claim 1, wherein the driving shaft and the driven shaft rotate integrally when their engaging portions engage with each other.   The drive shaft and the driven shaft are characterized in that when the engaging portions are not engaged with each other, one shaft presses in the axial direction to a position where the other shaft cannot engage with the other shaft. The blind drive device according to claim 2.   4. The blind driving device according to claim 2, wherein the drive shaft and the driven shaft rotate relatively until the engaging portions engage with each other. The drive shaft is constantly urged by the first urging means (123),
The driven shaft is always urged by the second urging means (133) so that the tip of the driven shaft is flush with the indoor surface of the second sash. The blind driving device according to any one of claims 2 to 4, wherein an urging force of the means is set smaller than an urging force of the first urging means. A blind driving device for driving a blind attached to a window frame,
An operation unit that is detachably attached to the blind and operates the drive of the blind;
A drive unit having a drive shaft (122) , detachably attached to the blind, and driven by operation of the operation unit;
A driven portion having a driven shaft (132) , provided on the blind and coupled to the drive portion to transmit power by driving the blind;
With
At least one of the drive shaft and the driven shaft is slidable in the axial direction by the biasing means (123, 133), and both the drive shaft and the driven shaft rotate around the shaft. Is free,
The drive shaft and the driven shaft are respectively provided with engaging portions (122a-1, 132a-1) that engage with each other ,
The drive device for a blind, wherein the drive shaft and the driven shaft rotate as a result of their engaging portions engaging with each other to transmit power.

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