JPH0967977A - Remote operation device for slide wing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily move a slide wing in a horizontal direction by remotely operating an actuator for causing the slide wing to travel forward or backward in such a state as vertically holding on a wing support means. SOLUTION: A horizontal slide glass window remote operation device is formed out of a through-fitting 51 driven forward with the first actuator 110 remotely operated via the manual operation of a handle, a lower guide rail 52 fixed to the through-fitting 51 for causing the right and left slide motion of a horizontal slide glass window 3, and a guide rail 51 where an engagement member 122 comes to be engaged. When the through-fitting 51 is pulled backward on the operation of' two lower actuators 110, the lower guide rail 52 is also driven together via a sash fitting metal 116 at the time of the backward motion of the through-fitting 51. The lower end of the horizontal slide glass window 3 is thereby remotely operated backward to such an extent as corresponding to a handle operation variable. Furthermore, the operation of the handle is complete, when the front of a fixed window glass becomes flush with the front of the horizontal slide glass window 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote operation device for a slide wing which can be remotely operated manually or automatically, and particularly to a water smooth moving glass window of an exhibition case in a front-back direction by remote operation manually or automatically. The present invention relates to a remote control device for a water-smooth moving glass window that can be moved to.

[0002]

2. Description of the Related Art Conventionally, a building, such as a museum, an art museum, an aquarium, a zoo, a botanical garden or a store, where people come and go, has an exhibition room (showroom) that houses exhibits such as works, articles and animals and plants. An exhibition case is installed. In such an exhibition case, the front and side surfaces are covered with transparent plate glass to make the exhibits easy to see and prevent the exhibits from being stolen or damaged. In order to appreciate (appreciate) the exhibit in the display case, the viewer (viewer) often looks from the front or side of the display case.

Further, in many display cases (so-called display cases and costume cases) for displaying small exhibits, a pull-type plate glass is installed upright on the front surface. However, in such an exhibition case, since the surfaces of the adjacent sheet glass are displaced, there are problems that the exhibits are difficult to see, the hermeticity is poor, and the appearance design is bad. Therefore, there is known an exhibition case in which the front surface is made to be the same surface by a plurality of plate glasses so that the exhibits can be easily seen, and the hermeticity and the appearance design are improved.

In such an exhibition case, when exchanging an exhibit, changing the position of the exhibit, or cleaning the inside, the operator opens the opening / closing doors provided on the side surface or the rear surface of the exhibit case. I often worked by getting inside. In addition, recently, if the exhibition case is protruding from the wall of the exhibition room, the passage for the viewer becomes narrower.Therefore, in order to effectively use the narrow exhibition room, there is also a type that stores the exhibition case on the wall of the exhibition room. It is getting more and more. With this type, it is difficult to install the door on the side or rear,
It is possible to arrange a glass window that can be opened and closed on the front of the display case.

[0005]

However, in an exhibition case having a glass window that can be opened and closed in the front, at least one glass window among a plurality of glass windows arranged upright so as to be flush with each other. I had to remove the window,
It is difficult to attach the flat glass to the display case again. Therefore, a water-smooth moving glass window is installed on the front of the display case so that one glass window is horizontally moved forward from the other glass windows and then horizontally moved along the guide rails. Types can be considered.

However, while holding the upper frame of the water smoothing glass window with one hand and supporting the lower frame with the other hand,
When manually opening the water smoothing glass window, it is very difficult to move the upper and lower frames in the same direction at the same time with the same amount upright. Occurs. Also, if the height of the water-smooth moving glass window is beyond the reach of people, or if the weight of the water-smooth moving glass window is very heavy, move the water-smooth moving glass window to the front side in an upright state. However, there is a problem that an exhibition case in which a glass window is installed so that the front surfaces thereof are flush with each other cannot be established.

[0007]

An object of the present invention is to provide a remote operation device for a slide wing, which is capable of moving the slide wing in the upright state in the front-rear direction even if the slide wing is large. To provide. An object of the invention described in claim 2 is to provide a remote operation device for a slide wing, which can be easily moved in the horizontal direction in a state where the slide wing is upright.

An object of the invention described in claim 4 is to provide a remote operation device for a slide wing, which makes it easier to look into the inside, and has improved hermeticity and appearance design. Another object of the present invention is to provide a remote operation device for a slide wing that can be easily moved in the horizontal direction even if the slide wing is arranged on the substantially same plane or substantially the same curvature surface as the upright wall body.

It is an object of the invention of claim 6 to move the slide wing in the up and down direction in an upright state without increasing the driving force of the actuator or increasing the strength of the wing supporting means. An object of the present invention is to provide a remote control device for a slide wing that can be used. It is an object of the invention as set forth in claim 11 to provide a slide wing remote control device that allows an operator to stop the slide wing at an arbitrary position.

According to a thirteenth aspect of the present invention, even if the slide wing is large, it is possible to move the slide wing upright in the front-rear direction and in the horizontal direction orthogonal to the front-rear direction. To provide an operating device.

[0011]

According to a first aspect of the present invention, there is provided a slide wing arranged upright, a wing support means for supporting the slide wing in an upright state, and the wing support means. A technical means is adopted which is provided with an actuator for moving the slide wing in the front-back direction and a remote operation means for remotely operating the actuator.

According to a second aspect of the present invention, in addition to the remote control device for a slide wing according to the first aspect, the wing support means is movable in a horizontal direction in which the slide wing is orthogonal to the front-rear direction. It is characterized by having a horizontal guide means for guiding so that Claim 3
In addition to the remote control device for a slide wing according to claim 2, the invention according to claim 2 is provided next to the slide wing,
A remote control device for a slide wing, which is characterized by arranging upright walls arranged upright in parallel.

According to a fourth aspect of the present invention, in addition to the remote control device for a slide wing according to the third aspect, one end face of the slide wing is substantially flush with or substantially flush with the wall surface of the upright wall body. It is characterized in that it is arranged on a curved surface. The invention described in claim 5 is claim 3 or claim 4.
In addition to the remote control device for a slide wing described in [3], the upright wall body is a water smooth motion wing capable of seeing through the inside.

According to a sixth aspect of the present invention, in addition to the remote operation device for a slide wing according to any one of the first to fifth aspects, the wing support means is so arranged that the wing support means moves in the front-rear direction. A front-back direction guiding means for supporting and guiding the means is provided. The invention according to claim 7 is characterized in that, in addition to the remote control device for a slide wing according to any one of claims 1 to 6, the slide wing is a water smooth motion wing capable of seeing through the inside. And

According to an eighth aspect of the present invention, in addition to the slide wing remote operation device according to any one of the first to seventh aspects, the remote operation means moves the wing support means in a front-rear direction. A remote operation unit for issuing a command to cause the actuator to operate and a command transmission unit for transmitting a command from the remote operation unit to the actuator are provided.

According to a ninth aspect of the present invention, in addition to the remote operation device for slide wings according to the eighth aspect, the remote operation section is a manually operated rotary manual operation means, and the command transmission is performed. The portion is a turning portion that turns the rotational movement of the manual operating means into a reciprocating movement in the axial direction, and a cord body that connects the turning portion and the actuator.

According to a tenth aspect of the present invention, in addition to the slide wing remote operation device according to the eighth aspect, the remote operation section is an electric signal for instructing to move the wing support means in the front-rear direction. Or an operation signal output means for outputting an operation signal such as a fluid pressure signal, and the command transmission part is a signal transmission means for transmitting an operation signal such as an electric signal or a fluid pressure signal from the operation signal output means to the actuator. It is characterized by being.

According to an eleventh aspect of the present invention, in addition to the slide wing remote operation device according to the ninth aspect, the remote operation means is provided with a state holding means for holding the state of the actuator. And According to a twelfth aspect of the present invention, in addition to the slide wing remote control device according to any one of the first to eleventh aspects, the actuator pushes the wing supporting means forward, and the actuator. It is characterized in that a pulling back means for pulling back the wing support means to the rear side is provided.

According to the thirteenth aspect of the present invention, there are provided slide wings arranged upright and horizontal guide means for guiding the slide wings so as to be movable in a horizontal direction orthogonal to the front-rear direction. The wing support means for supporting the slide wing in an upright state, the first actuator for moving the horizontal guide means in the front-rear direction of the slide wing, and the slide wing along the horizontal guide means. The technical means including the second actuator for horizontally moving the first actuator and the second actuator for remotely operating the second actuator is adopted.

According to a fourteenth aspect of the present invention, in addition to the remote operation device for slide wings according to the thirteenth aspect, the remote operation means gives a first remote commanding instruction to move the slide wing from a fixed position. An operation unit, a second remote operation unit for instructing the slide wing to return to a fixed position, a first position detecting means for detecting that the slide wing has reached a fixed position, and the slide wing has reached the forward completion position. Second position detecting means for detecting that
Third position detecting means for detecting that the slide wing has reached a horizontal one side completion position that is the same position as the forward movement completed position, and detecting that the slide wing has reached the other horizontal side completion position And a switching control device for controlling the first actuator and the second actuator according to the outputs of the first and second remote operation units and the first to fourth position detecting means. It is characterized by

According to a fifteenth aspect of the present invention, in addition to the slide wing remote control device according to the thirteenth or fourteenth aspect, the first actuator is an electric motor attached to the wing support means. It is characterized by According to a sixteenth aspect of the present invention, in addition to the slide wing remote control device according to the thirteenth or fourteenth aspect, the second actuator is an electric motor attached to the wing support means. And

[0022]

According to the invention described in claim 1, the wing support means is moved to the front side or the rear side of the slide wing by remotely operating the actuator by the remote operation means. Therefore, even if the slide wing supported by the wing support means in an upright state moves to the front side or the rear side, even if the slide wing has a large height that humans cannot reach,
The upper and lower ends of the slide wings can be simultaneously moved in the same direction and in the same amount by a simple operation.

According to the second aspect of the invention, the slide wing moved to the front side or the rear side is manually, mechanically or mechanically moved in the horizontal direction orthogonal to the front-rear direction of the slide wing by the horizontal guide means. It can be moved electrically with a simple operation. According to the third and fourth aspects of the present invention, since the one end surface of the slide wing and the wall surface of the upright wall body are installed upright on substantially the same plane or substantially the same curvature surface, it is hermetically sealed. Excellent in design and appearance.

According to the first to fourth aspects of the invention, the wing support means is moved to the front side or the rear side of the slide wing by remotely operating the actuator by the remote operation means. Therefore, the slide wings supported in the upright state by the wing support means move to the front side or the rear side, so that the slide wings are arranged on the substantially same plane or substantially the same curvature surface as the upright wall body. Can also be easily moved horizontally.

According to the invention of claim 5, it is easy to look inside. According to the invention described in claim 6, since the wing support means is supported and guided by the front-back direction guide means so as to be easily moved to the front side or the rear side, the driving force of the actuator is increased or the wing support is performed. The slide wing can be moved in the front-rear direction in the upright state without increasing the strength of the means. According to the invention of claim 7, it is easy to look inside.

According to the invention described in claim 8, when a command is issued from the remote operation part to move the wing support means to the front side or the rear side, the command transmission part issues the command of the remote operation part to the actuator. The actuator is remotely operated by transmitting to the.

According to the ninth aspect of the invention, when the rotary manual operating means is manually operated, the rotary motion of the manual operating means is input to the turning portion. Then, the turning movement of the manual operation means is turned into the axial reciprocating movement at the turning portion. The actuator is remotely operated by the cord body receiving the axial reciprocating motion.

According to the tenth aspect of the present invention, when an operation signal such as an electric signal or a fluid pressure signal is output from the operation signal output means to move the wing support means in the front-rear direction, the signal transmission means operates. The actuator is remotely operated by transmitting the operation signal to the actuator.

According to the eleventh aspect of the present invention, by providing the remote control means with the state holding means for holding the state of the actuator, the wing support means is stopped at an arbitrary position by the remote control of the actuator by the remote control means. . For this reason, the operator can stop the slide wing at an arbitrary position, so that the operator can be prevented from being caught by the slide wing.

According to the twelfth aspect of the invention, the wing supporting means is pushed forward by the pushing means, so that the slide wing is moved forward in an upright state. Further, the wing support means is pulled back by the pullback means, so that the slide wing is moved to the rear side in the upright state. Thereby, the upper end and the lower end of the slide wing can be moved toward the front side or the rear side at the same time in the same direction by the same amount.

According to the thirteenth aspect of the present invention, by remotely operating the first actuator by the remote operation means, the horizontal guide means of the wing support means moves to the front side or the rear side of the slide wing. Therefore, the slide wing supported by the wing support means in an upright state moves to the front side or the rear side. Further, by remotely operating the second actuator by the remote operation means, the slide wing moves in the horizontal direction orthogonal to the front-back direction of the slide wing along the horizontal guide means. Therefore, even if the slide wing has a large height that cannot be reached by humans, the upper and lower ends of the slide wing should be moved in the same direction at the same time.
The same amount can be moved with simple work.

[0032]

BEST MODE FOR CARRYING OUT THE INVENTION A remote operation device for a slide wing according to the present invention will be described based on an embodiment applied to a remote operation device for a water smoothing moving glass window installed so that the entire front surface of the display case is flush with the front surface. .

[Structure of First Embodiment] FIGS. 1 to 10 show a first embodiment of the present invention, and FIG. 1 is a view showing an outline of the entire structure of a remote control device for a water smoothing moving glass window. so,
FIG. 2 is a diagram showing an exhibition case.

The water-smooth moving glass window remote control device 1 is assembled in an exhibition case 2 of a type to be embedded in the wall of an exhibition room of a building such as a museum, and the water-smooth moving glass window attached to the front of the exhibition case 2. 3 is a front-rear direction moving device that moves 3 to the front side or the rear side by remote control by manual operation.

The remote control device 1 for the water smoothing moving glass window is
The water smoothing glass window 3 of the display case 2 and the lower glass window supporting unit 7 that supports the lower end of the water smoothing glass window 3
(See FIG. 5), an upper glass window support unit 8 (see FIG. 8) for supporting the upper end of the water smoothing glass window 3, and a lower side,
A water smoothing moving glass window opening / closing assisting device 9 for moving the water smoothing moving glass window 3 in the front-rear direction via the upper side glass window supporting units 7 and 8 is provided.

Next, the display case 2 will be described with reference to FIGS. The display case 2 includes two water-smooth moving glass windows 3, a plurality of fixed glass windows 4 (eight in this example) arranged between them, and a lower window frame unit 5 installed on the lower side. , An upper window frame unit 6 installed on the upper side, left and right upright units (not shown), and the like. The display case 2 is installed so that the front surfaces of the two water-smooth moving glass windows 3 and the front surfaces of the plurality of fixed glass windows 4 are located on the same plane. The pillars and walls of the exhibition room and the front surface of the exhibition case 2 may be flush with each other.

Next, the water smoothing moving glass window 3 will be described with reference to FIGS. 1 and 2 and FIGS. 4 to 10. The water smoothing glass window 3 is a slide wing according to the present invention, and has a rectangular shape with a height (vertical dimension) of 2700 mm, a lateral dimension (horizontal dimension) of 2100 mm, and a thickness of 34 mm, for example. are doing. Water smooth moving glass window 3
Is a transparent flat plate glass (hereinafter referred to as a flat glass) 11 provided to make it easy to see the exhibits housed in the display case 2, and a pair of lower side frames 12 for holding the lower portion of the flat glass 11. , 13, and a pair of upper side frames 14 and 15 for holding the upper portion of the flat glass 11.

As shown in FIGS. 4 to 7, the pair of lower side frames 12 and 13 are made of a metal plate such as iron and extend in the width direction (left-right direction) of the display case 2. The lower portion of the flat glass 11 is held between the pair of lower side frames 12 and 13 via a caulking material (filler) 16 such as rubber. The front lower frame 12 is extended below the rear lower frame 13. Further, handles 17 for moving the water-smooth moving glass window 3 in the left-right direction are fastened and fixed to a plurality of positions on the lower frame 12 on the front side.

Further, between the pair of lower side frames 12 and 13, a lower frame member 19 which abuts on the lower end surface of the flat glass 11 via a rubber member 18, and a pair of lower side members via the lower frame member 19. A mounting bracket 20 for fixing the frames 12, 13 by tightening or welding is attached. A plurality of round rod-shaped support shafts 21 (four in this example) are provided on the lower side surface of the mounting member 20 so as to project rearward. A lower roller 22 made of metal or resin is rotatably supported on the support shafts 21. A peripheral groove 23 as an engaged portion is formed on the outer peripheral surface of the lower roller 22.

As shown in FIGS. 8 to 10, the pair of upper side frames 14 and 15 are made of a metal plate such as iron and extend in the width direction (left-right direction) of the display case 2. The upper portion of the flat glass 11 is held between the pair of upper side frames 14 and 15 via a caulking material (filler) 24 such as rubber.

At the upper ends of the pair of upper side frames 14 and 15,
The upper frame member 2 is tightened or welded to the lower side frame 12 on the front side.
5 is fixed. A mounting bracket 27 having a support shaft 26 is fixed to the upper end of the upper frame member 25 by tightening or welding. A plurality of round bar-shaped support shafts 26 (four in this example) are formed on the lower side surface of the mounting bracket 27 so as to project rearward.

The support shaft 26 is composed of a head and legs, and is fixed to the fitting 27 by caulking the tips of the legs. An upper roller (engaged portion) 28 made of metal or resin is rotatably supported on the support shaft 26. As shown in FIG. 9, the round hole 27a of the mounting member 27 and the round hole 28a of the upper roller 28 have a difference in inner diameter, so that a step 26a is provided in the middle of the leg of the support shaft 26. ing. Since the step 26a is provided on the support shaft 26, the length of the leg portion of the support shaft 26 is shortened when the tip ends of the leg portions of the support shaft 26 are caulked, and the upper roller 28 becomes difficult to rotate. Can be prevented.

Next, the fixed glass window 4 will be described with reference to FIGS. 1 and 2. The fixed glass window 4 is an upright wall body of the present invention, and is a transparent flat plate glass (hereinafter referred to as flat glass) 29, and a pair of lower side frames (not shown) that hold the lower portion of the flat glass 29. , And a pair of upper side frames (not shown) for holding the upper portion of the flat glass 29.

Next, the lower window frame unit 5 is shown in FIG.
7 will be described with reference to FIG. The lower side window frame unit 5 includes a lower side window frame 31 extending in the left-right direction and a rear side frame 3 standing upright from the rear side of the lower side window frame 31.
2, a lower side cover 33 rotatably supported on the front side of the lower side window frame 31, a foundation 34 on which the lower side window frame 31 is placed, and the like.

The lower window frame 31 is formed into a box shape by pressing a metal plate, and a reinforcing material is applied to an appropriate place. The lower window frame 31 is fixed to a pair of uprights (not shown) by tightening or welding. At the upper end of the rear side frame 32, a rubber seal 35 is mounted between the lower side frame 13 on the rear side of the water smoothing moving glass window 3 and the lower side frame (not shown) on the rear side of the fixed glass window 4. There is. The rubber seal 35 has a sealing function of making the upper and lower spaces airtight, and a damper function of softening the impact when the water smoothing glass window 3 collides with the rear side frame 32 when the water smoothing glass window 3 is returned to a fixed position. Have

The lower cover 33 is rotatable by, for example, 90 ° to 170 ° with respect to the vertical direction by a hinge 36 (see FIG. 5) attached to the front side of the lower window frame 31, and the upper end portion is A lip seal 37 is attached between the lower side frame 12 on the front side of the water smooth moving glass window 3 and the lower side frame (not shown) on the front side of the fixed glass window 4. Lip seal 3
7 is held on the lower side frame 12 on the front side of the water smoothing moving glass window 3 and on the lower side frame on the front side of the fixed glass window 4, and has a sealing function of making the upper and lower spaces airtight and a lower side cover 33 at a fixed position. The lower side cover 33 when it is returned to
It has a damper function to soften the impact when it collides with.

The foundation 34 is made of reinforced concrete, steel frame or the like, and has two plaster boards 38 mounted on the front surface.
The plasterboard 38 on the front side is decorated to improve the appearance design.

Next, the upper window frame unit 6 is shown in FIG.
This will be described with reference to FIG. The upper side window frame unit 6 includes an upper side window frame 41 extending in the left-right direction, a rear side frame 42 standing upright from the rear side of the upper side window frame 41, and an upper side window frame 41. An upper cover 43 rotatably supported on the front side is provided. Upper window frame 4
1 is formed into a box shape by pressing a metal plate, and a reinforcing material is applied to an appropriate place. The upper window frame 41 is fixed to a pair of not-shown halves by tightening or welding.

The upper end of the rear frame 42 and the upper cover 43
A rubber seal 44 is attached between the upper end and the upper end of the. The rubber seal 44 has a sealing function of making the upper and lower spaces airtight, and a damper function of softening the impact when the upper cover 43 collides. At the lower ends of the upper side window frame 41 and the rear side frame 42, between the upper side frame 15 on the rear side of the water smoothing moving glass window 3 and the upper side frame (not shown) on the rear side of the fixed glass window 4. A rubber seal 45 is attached. The rubber seal 45 has a sealing function of making the upper and lower spaces airtight, and a damper function of softening the shock when the water smoothing glass window 3 collides with the upper side window frame 41 when the water smoothing glass window 3 is returned to a fixed position. have.

Upper side cover 4 on the upper side of the water smoothing glass window 3
3 can move integrally with the water smooth moving glass window 3,
The upper cover 43 on the upper side of the fixed glass window 4 is fixed. A lip seal 46 is mounted between the lower end of the upper cover 43 and the upper frame 14 on the front side of the water smoothing glass window 3 and the upper frame (not shown) on the front side of the fixed glass window 4. The lip seal 46 is held by the upper side frame 14 on the front side of the water smoothing glass window 3 and the upper side frame on the front side of the fixed glass window 4, and has a sealing function of making the upper and lower spaces airtight and the upper side cover 43. The upper cover 43 when returned to the fixed position
Has a damper function to soften the impact when it collides with the water smooth moving glass window 3.

Next, the lower glass window supporting unit 7 will be described with reference to FIGS. The lower side glass window supporting unit 7 is a wing supporting means of the present invention, and is a through fitting 51 provided on the upper end surface of the lower side window frame 31 of the lower side window frame unit 5 so as to be movable in the front-rear direction, Further, it has a lower side guide rail 52 fixed to the upper end surface of the through fitting 51 by tightening or welding.

The through fitting 51 is formed by pressing a metal plate into a substantially square V shape, and has a width dimension of the water smooth moving glass window 3 and a width of the fixed glass window 4 adjacent to the water smooth moving glass window 3. It is extended in the left-right direction of the display case 2 by the length including the dimensions. The lower guide rail 52 is the horizontal guide means of the present invention, and is formed by pressing a metal plate into a substantially L shape. This lower guide rail 52 is
The water smooth moving glass window 3 has an engaging piece 53 as an engaging portion with which the circumferential groove 23 formed on the outer peripheral surface of the lower roller 22 engages, and supports the water smooth moving glass window 3 in the left-right direction by hand. It is a lower horizontal guide means for guiding.

Next, the upper glass window support unit 8 will be described with reference to FIGS. The upper side glass window supporting unit 8 is a wing supporting means of the present invention, and a through fitting 54 provided on the upper end surface of the upper side window frame 41 of the upper side window frame unit 6 so as to be movable in the front-rear direction, It has a slide fitting 55 fixed to the lower end surface of the through fitting 54 by welding or the like, and an upper guide rail 56 fixed to the lower end surface of the slide fitting 55 by tightening or welding.

The metal fitting 54 is formed by pressing a metal plate into a substantially square V shape, and is similar to the metal fitting 51 in that the width of the water smooth moving glass window 3 is adjacent to the water smooth moving glass window 3. The display case 2 is extended in the left-right direction by a length including the width of the fixed glass window 4 provided. Reference numeral 58 is a reinforcing member having a U-shaped cross section for reinforcing the through fitting 54. The slide fitting 55 is formed by pressing a metal plate into a substantially U-shape, and the dimension of the upper end side wall in the front-rear direction is longer than the dimension of the lower end side wall in the front-rear direction. The front end side wall of the slide fitting 55 is fixed to the back surface of the upper cover 43 by tightening or welding.

The upper guide rail 56 is the horizontal guide means of the present invention and is formed by pressing a metal plate into a substantially U shape. The upper guide rail 56 is
The upper horizontal guide means has an engaging groove 57 as an engaging portion with which the upper roller 28 of the water smooth moving glass window 3 is engaged, and manually supports and guides the water smooth moving glass window 3 in the left-right direction. .

Next, the opening / closing assisting device 9 for a water smoothing moving glass window of this embodiment will be described with reference to FIGS. 1 and 3 to 10. The water smoothing glass window opening / closing auxiliary device 9 includes a remote control unit 60, a transmission unit 70, a lower drive unit 100, and an upper drive unit 200.

Next, the remote control unit 60 will be described with reference to FIGS. 1, 3 and 4. The remote control unit 60 is a remote control means of the present invention, and is a handle that is disposed between the water smoothing glass window 3 and the fixed glass window 4 adjacent to the water smoothing glass window 3 and is manually operated. 6
1, a telescopic shaft 62 that rotates integrally with the handle 61,
Coil spring 6 for urging the telescopic shaft 62 forward
3, a support cylinder 6 slidably supporting the rear end of the telescopic shaft 62
4 and the lower side window frame unit 5 has a substrate 65 and the like which are clamped and fixed to the upper end surface of the lower side window frame 31.

The handle 61 holds the lower cover 33 of the lower window frame unit 5 when the lower cover 33 is closed.
It is housed in contact with the back surface of the. The handle 61 is the rotary manual operating means of the present invention,
When the lower cover 33 is opened, for example, 45 mm to the front side
It is held in a protruding state only. This handle 61
When the operator rotates right, the water smooth moving glass window 3 is moved to the front side (open side), and when the operator rotates left, the water smooth moving glass window 3 is moved to the front side (open side).

The telescopic shaft 62 includes a mounting member 66 and a guide member 6.
7 and a support cylinder 64 are slidably supported, and an annular plate-shaped retainer 68 is attached to the outer periphery of the central portion. A front end of the coil spring 63 is held by a retainer 68, a rear end of the coil spring 63 is held by a mounting member 66, and the coil spring 63 is spirally wound around the outer circumference of the telescopic shaft 62. The support cylinder 64 holds a coil spring 69 between itself and the mounting fitting 66. The base plate 65 has a support cylinder 64, a mounting bracket 66, and a guide bracket 67 fastened and fixed to its upper end surface.

Next, the transmission unit 70 will be described with reference to FIGS. This transmission unit 70 is
The remote control means of the present invention includes a turning box 71, main pipes 72 and 73, a connecting pipe 74, and the like. The turning box 71 is the turning portion of the present invention, and slidably holds the input shaft 75 connected to the telescopic shaft 62 via a power transmission mechanism (not shown) and a geared cable (push-pull cable). The output unit 76 and a gear unit (not shown) that turns the rotational movement of the input shaft 75 into the axial reciprocating movement of the geared cable in the output unit 76 are provided. This gear device includes a lower drive unit 10
A self-locking mechanism (state holding means) for holding the states of 0 and the upper drive unit 200 is configured.

In the main pipes 72 and 73, the output unit 7
A geared cable connected to the geared cable in 6 is slidably accommodated. A geared cable connected to the geared cables in the main pipes 72 and 73 is slidably accommodated in the connection pipe 74. These transmission units 70 provide the lower drive unit 100 and the upper drive unit 200 with the axial reciprocating motion of the geared cable.

The higher the height of the display case 2 is, the longer the axial dimension of the geared cable in the connecting pipe 74 may be. Further, the larger the widths of the water smoothing glass window 3 and the fixed glass window 4 adjacent to the water smoothing glass window 3, the longer the geared cables in the main pipes 72, 73 may be made.

Next, the lower drive unit 100 will be described with reference to FIGS. 1 and 5 to 7. The lower drive unit 100 includes two lower actuators 110 that drive the lower glass window support unit 7 forward or backward, and a lower guide that supports and guides the lower glass window support unit 7 in the front-rear direction. It is composed of a unit 120 and the like.

Next, the lower actuator 110 will be described with reference to FIGS. 1, 5 and 6. The two lower side actuators 110 are lower side drive means and push-pull means for moving the water smoothing glass window 3 in the front-rear direction, and are circular pipes connected to the main pipe 72 via a joint (not shown). 111, a case 113 in which the chain 112 appears and disappears from the inside, and this case 113
It is composed of a bracket 114 and the like for mounting the. The geared cable in the main pipe 72 is slidably inserted into the circular pipe 111.

A flat plate-shaped connecting piece 115 is integrally attached to the tip of the chain 112. The connecting piece 115 is fastened and fixed to the shoji metal fitting 116 by using a fastener such as a screw. The shoji metal fitting 116 is fastened and fixed to the lower end surface of the through metal fitting 51 of the lower glass window support unit 7 by using a fastener such as a screw.

The case 113 is fastened and fixed to the upper end surface of the bracket 114 by using fasteners such as bolts. Inside the case 113, the lower glass window support unit 7 is formed by projecting the chain 112 forward.
Means for pushing out the front side and the chain 112
It has a built-in pulling back means for pulling back the lower glass window supporting unit 7 to the rear side by pulling back. The bracket 114 is fastened and fixed to the upper end surface of the lower window frame 31 of the lower window frame unit 5 by using a fastener such as a bolt.

Next, the lower guide unit 120 will be described with reference to FIGS. 5 and 7. This lower side guiding unit 120 is the front-back direction guiding means of the present invention,
Water smooth moving glass window 3 through lower glass window supporting unit 7
Is a lower-side front-back direction guiding means for guiding the lower end portion of the frame, that is, the lower-side frames 12, 13 forward or backward. The lower guide unit 120 includes a guide rail 121 that supports the lower glass window support unit 7, and an engaging member that guides the lower glass window support unit 7 along the extension direction of the guide rail 121. It is composed of 122 and the like.

The guide rail 121 is fixed to the upper end surface of the lower window frame 31 of the lower window frame unit 5 by tightening or welding. The guide rail 121 has a length obtained by adding the amount of movement of the water smoothing glass window 3 in the front-rear direction (for example, 45 mm) and the dimension of the engagement member 122 in the front-rear direction (for example, 90 mm), and engages with both side surfaces. The engaging groove 123 with which the member 122 is engaged is formed, respectively. These engagement grooves 1
23 is extended in the front-back direction. A regulation plate (stopper) 124 that regulates the forward movement of the engaging member 122 is fixed to the front end of the guide rail 121 by tightening or welding.

The engaging member 122 is fixed to the lower end surface of the through fitting 51 of the lower glass window supporting unit 7 by tightening or welding. The engaging member 122 is slidably movable on the guide rail 121 and engages with the engaging grooves 123 on both sides of the guide rail 121 on both sides.
5 respectively. These engaging arms 125 are formed in a U-shaped cross section so as to hold the upper end portion of the guide rail 121.

Next, the upper drive unit 200 will be described with reference to FIGS. 1 and 8 to 10. The upper drive unit 200 includes an upper glass window support unit 8
Is composed of two upper side actuators 210 for driving the front side or the rear side, and an upper side guiding unit 220 for supporting and guiding the upper side glass window supporting unit 8 in the front-rear direction.

Next, the upper actuator 210 will be described with reference to FIGS. 1, 8 and 9. These two upper side actuators 210 are an upper side driving means and a push-pull means for moving the water smoothing moving glass window 3 in the front-rear direction, and like the lower side actuator 110, they are jointed to the main pipe 73 (not shown). ), A circular pipe 211, a case 213 in which the chain 212 appears and disappears from the inside, a bracket 214 for attaching the case 213, and the like. The geared cable in the main pipe 73 is slidably inserted in the circular pipe 211.

A flat plate-shaped connecting piece 215 is integrally attached to the tip of the chain 212. The connecting piece 215 is fastened and fixed to the shoji metal fitting 216 by using a fastener such as a screw. The shoji metal fitting 216 is fastened and fixed to the side surface of the through metal fitting 54 of the upper glass window support unit 8 by using a fastener such as a screw.

The case 213 is fixed to the upper end surface of the bracket 214 by using fasteners such as bolts. In this case 213, the upper side glass window support unit 8 is formed by protruding the chain 212 to the front side.
Means for pushing out the front side and the chain 212
It has a built-in pulling back means for pulling back the upper glass window support unit 8 to the rear side by pulling back. The bracket 214 is fastened and fixed to the upper end surface of the upper window frame 41 of the upper window frame unit 6 by using a fastener such as a bolt.

Next, the upper guide unit 220 will be described with reference to FIGS. 8 and 10. This upper side guiding unit 220 is the front-back direction guiding means of the present invention, and the upper side of the water-smooth moving glass window 3, that is, the upper side frames 14 and 15 is forward or backward via the upper side glass window supporting unit 8. It is an upper-side front-back direction guiding means for guiding to the side. The upper guide unit 220, like the lower guide unit 120, guides the guide rail 221 that supports the upper glass window support unit 8 and the upper glass window support unit along the extension direction of the guide rail 221. It is composed of an engaging member 222 and the like for guiding 8. Note that the weight of the water-smooth moving glass window 3 can be held by the two upper guide units 220.

The guide rail 221 is fixed to the upper end surface of the upper window frame 41 of the upper window frame unit 6 by tightening or welding. The guide rail 221 has a length obtained by adding the amount of movement of the water smooth moving glass window 3 in the front-rear direction (for example, 45 mm) and the dimension of the engaging member 222 in the front-rear direction (for example, 90 mm), and engages with both side surfaces. Engagement grooves 223 with which the members 222 engage are formed respectively.

The engaging member 222 is fixed to the lower end surface of the upper end side wall of the slide fitting 55 of the upper glass window supporting unit 8 by tightening or welding. The engaging member 222 is slidably movable on the guide rail 221, and has engaging arms 225 on both sides that engage with the engaging grooves 223 on both sides of the guide rail 221. These engaging arms 225 are formed to have a U-shaped cross section so as to hold the upper end portion of the guide rail 121.

[Operation of First Embodiment] Next, a method of using the remote control device 1 for a water smoothing moving glass window according to this embodiment will be described with reference to FIGS. 1 to 10.

When opening the water smoothing moving glass window 3 of the display case 2, first, the lower side cover 33 of the lower side window frame unit 5 is opened. When the lower cover 33 is opened, the handle 61 and the telescopic shaft 62 housed in the lower window frame unit 5 are pushed forward by the elastic force of the coil spring 63 to a position where the handle 61 can be easily rotated.

Next, when the operator rotates the handle 61 to the right (forward rotation), the extension shaft 62 and the input shaft 75 of the turning box 71 also rotate to the right. Then, the gear device in the turning box 71 turns the rotational movement of the input shaft into the outward movement of the geared cable in the output portion 76 in the axial direction, so that the geared device is inserted through the main pipes 72 and 73 and the connecting pipe 74. The cable slides to one side in the axial direction. Therefore, the two lower actuators 110 and 2
The upper actuators 210 start to operate.

The two lower side actuators 110 and the two upper side actuators 210 are connected to the main pipe 7.
Since power corresponding to the amount of axial movement of the geared cable in 2, 73 is applied, this power is applied to the chain 112,
Convert to an extrusion rate of 212. And the chain 11
By pushing 2, 212 forward, the fittings 51, 54 of the lower and upper glass window support units 7, 8 are driven forward through the shoji fittings 116, 216.

At this time, the engaging arm 125 of the engaging member 122 fixed to the lower end surface of the through fitting 51 is engaged with the engaging groove 123 of the guide rail 121 fixed to the upper end surface of the lower window frame 31. The engaging member 122 moves along the extension direction of the guide rail 121, that is, the front-rear direction.

Therefore, the threaded fitting 51 smoothly moves to the front side with a small operating force, so that the threaded fitting 5
Since the lower guide rail 52 fixed to the upper end surface of 1 is also driven forward, the pair of lower frames 12, 13 are pushed forward through the lower roller 22 and the support shaft 21. Therefore, the lower end of the water smoothing glass window 3 is remotely operated to the front side by the operation amount (rotation angle) of the handle 61.

On the other hand, when the through fitting 54 is driven forward, the slide fitting 55 fixed to the lower end surface of the through fitting 51 is also driven forward. At this time, the engaging arm 225 of the engaging member 222 fixed to the upper end side wall of the slide fitting 55 is engaged with the engaging groove 223 of the guide rail 221 fixed to the upper end surface of the upper window frame 41, The engagement member 222 moves along the extension direction of the guide rail 221, that is, the front-back direction.

Therefore, the slide fitting 5 can be operated with a small operating force.
By the smooth movement of 5 to the front side, the upper cover 43 and the upper guide rail 56 fixed to the lower end side wall of the slide fitting 55 are also driven forward, so that the upper roller 28 and the mounting fitting 27 are attached. The pair of upper side frames 14 and 15 are pushed forward through the upper frame member 25. Therefore, the upper end of the water smoothing glass window 3 and the upper cover 43 are remotely operated to the front side by the operation amount (rotation angle) of the handle 61.

As described above, the water smoothing glass window 3 is moved to the front side in the upright state by the operation amount of the handle 61, and at any position until the engaging member 122 comes into contact with the regulating plate 124 of the guide rail 122. The movement of the water smoothing glass window 3 is stopped. At this time, if the water-smooth moving glass window 3 is pushed forward of the front surface of the fixed glass window 4, the operator can handle 1
When 7 is gripped and a force is applied to the fixed glass window 4 side adjacent to the water smooth moving glass window 3, the lower roller 22 slides along the engaging piece 53 of the lower guide rail 52.

Further, as the upper roller 28 slides along the engaging groove 57 of the upper guide rail 56, the water smoothing moving glass window 3 horizontally slides leftward or rightward. Therefore, a part of the front surface of the display case 2 is opened so that the operator can enter the display case 2.
Exchanging works such as goods and works can be carried out as moving work.

The water-smooth moving glass window 3 of the display case 2
When performing the closing work of No. 1, first, the water-smooth moving glass window 3 is slid in the opposite direction to the position where it does not overlap the adjacent fixed glass window 4. Then, by rotating the handle 61 counterclockwise (reverse rotation), the geared cable inserted through the main pipes 72, 73 and the connection pipe 74 slides to the other side in the axial direction, and the two lower actuators 110 and The two upper actuators 210 start the operation opposite to the above.

That is, the two lower side actuators 1
By pulling back the chains 112 and 212 of the 10 and two upper side actuators 210 to the rear side,
Through the shoji metal fittings 116 and 216, the through metal fittings 51 and 54 are driven rearward. At this time, the lower guide rail 52 is also driven rearward by receiving the action of the guide rail 121 and the engaging member 122 and smoothly moving the through metal fitting 51 rearward with a small operating force. A pair of lower side frames 12, 1 via side rollers 22 and support shafts 21.
3 is pulled back to the rear side. Therefore, the lower end of the water smoothing glass window 3 is remotely operated to the rear side by the operation amount (rotation angle) of the handle 61.

On the other hand, the guide rail 221 and the engaging member 222
In response to the above action, the slide metal fitting 55 smoothly moves to the front side with a small operating force, and the upper guide rail 56 and the upper cover 43 are also driven to the front side. 27, upper frame material 25
The pair of upper side frames 14 and 15 are pulled back to the rear side via the. Therefore, the upper end of the water smoothing glass window 3 and the upper cover 43 are remotely operated rearward by the operation amount (rotation angle) of the handle 61.

As described above, the water smoothing moving glass window 3 was moved rearward by the operation amount of the handle 61 in an upright state, and the front surface of the fixed glass window 4 and the front surface of the water smoothing moving glass window 3 were flush with each other. In other words, the rear lower frame 13 and the upper frame 15 are rubber seals 35, 45 of the rear side frames 32, 42.
The operation of the handle 61 ends when it comes into contact with. As a result, the entire front surface of the display case 2 becomes the same surface, the displayed product is easy to see, the appearance is excellent, and the fixed glass window 4 and the water-smooth moving glass window 3 are not misaligned, which is excellent in hermeticity. Then, when the lower cover 33 is closed by using the hinge 36 as a fulcrum, the handle 61 and the telescopic shaft 62 overcome the elastic force of the coil spring 63 and are returned to the positions shown in FIGS. 3 and 4, and the handle 61 is stored. To be done.

[Effects of the First Embodiment] As described above, in the remote control device 1 for a water smoothing glass window of this embodiment, the front surface of the entire display case 2 is the same surface, and the water smoothing glass window 3 is Even if the height is out of the reach of a person, the water smooth moving glass window 3 is upright, that is, the pair of upper side frames 14 and 15 of the water smooth moving glass window 3 are paired with the lower side frames 12,
Simultaneously with 13, it can be easily moved by the same direction and the same amount to the front side or the rear side by remote control by manual operation.

Further, since the water smoothing moving glass window 3 and the lower side and upper side guiding units 120 and 220 for supporting and guiding the lower side and upper side glass window supporting units 7 and 8 in the front-rear direction are provided, the water smoothing moving glass window is provided. 3 and the lower and upper glass window supporting units 7 and 8 move smoothly with a small driving force (operating force). Therefore, the driving force of the chains 112 and 212 of the lower and upper actuators 110 and 210 is increased, and the lower and upper glass window supporting units 7 and 8 are provided.
It is not necessary to increase the strength of the.

Further, since the gear device in the turning box 71 is provided with a self-locking mechanism for holding the operating states of the lower and upper drive units 100 and 200, the operator can set the water smoothing glass window 3 at any position. Since the lower and upper glass window supporting units 7 and 8 can be stopped, the usability is excellent. Further, even if an external force for moving the water smooth moving glass window 3 back and forth is applied during the remote operation, the water smooth moving glass window 3, lower side, upper side glass window supporting units 7, 8 and lower side, upper side driving units 100, 200, etc. Does not move back and forth. This is particularly effective when closing the water-smooth moving glass window 3 when closing it.

The exhibition case 2 is housed on the wall of the exhibition room so that the front surface of the exhibition case 2 is flush with the walls of the exhibition room and the end faces of the pillars, so that the narrow exhibition room can be effectively used. it can. In addition, since the wall surface of the exhibition room and the end surface of the pillar, the front surface of the water-smooth moving glass window 3 and the front surface of the fixed glass window 4 are all on the same surface, the appearance is very excellent.

[Second Embodiment] FIG. 11 shows a second embodiment of the present invention, and is a view showing the lower end structure of a water-smooth moving glass window. In this embodiment, the lower roller 22 is rotatably supported by a mounting bracket 30 having a U-shaped cross section. The mounting bracket 30 is fastened and fixed to the mounting bracket 20 with a fastener such as a screw.

[Third Embodiment] FIG. 12 shows a third embodiment of the present invention and is a view showing an electrically operated opening / closing assisting device for a water smoothing dynamic glass window. The electrically operated water-smooth moving glass window opening / closing auxiliary device 300 of this embodiment includes an operation box 31.
0, signal transmission lines 321, 322, first and second electric drive units 330, 340, and lower and upper drive units 100, 200 having the same structure as the first embodiment.

The operation box 310 is the remote operation unit of the present invention, and has a built-in microcomputer.
An opening switch 311, a closing switch 312 and a stop switch 313 are installed on the surface. Open switch 3
Reference numeral 11 is an operation signal output means for outputting an operation signal instructing to move the water smoothing glass window 3 to the front side.
The operation box 310 is replaced with a remote controller which is a radio device (transmitter), and receivers are attached to the first and second electric drive devices 330 and 340, and the signal transmission line 3
21,322 may be abolished.

The closing switch 312 is the water smoothing glass window 3
Is an operation signal output means for outputting an operation signal for instructing to move to the rear side. The stop switch 313 is an operation signal output means that outputs an operation signal for instructing to stop the movement of the water smoothing glass window 3. Signal transmission line 3
Reference numerals 21, 322 are command transmission units of the present invention, and are signal transmission means for transmitting the operation signals of the opening switch 311, the closing switch 312, and the stop switch 313 to the electric drive devices 330, 340.

The electric drive devices 330 and 340 constitute an electric actuator together with the lower and upper actuators 110 and 210 and the geared cables in the main pipes 72 and 73. The electric drive devices 330 and 340 have a gear device and an electric motor built therein, and an operating voltage is supplied from a power supply circuit 350.
The electric drive units 330 and 340 are provided with the opening switch 31.
1. Based on the operation signals of the closing switch 312 and the stop switch 313, the geared cables in the main pipes 72 and 73 are pushed out, pulled back, or stopped moving.

[Fourth Embodiment] FIG. 13 shows a fourth embodiment of the present invention and is a view showing an exhibition case. In this embodiment, the curved surface glass 81, 82 having an arc-shaped cross section is used for the water smooth moving glass window 3 and the fixed glass window 4, so that the front surface of the display case 2 has the same curvature surface.

[Fifth Embodiment] FIG. 14 shows a fifth embodiment of the present invention and is a view showing an exhibition case. In this embodiment, the fixed glass window 4 is formed by using the curved glass 81 having an arc-shaped cross section only in the water smooth moving glass window 3.
Both side portions and the water-smooth moving glass window 3 are flush with each other.

[Sixth Embodiment] FIGS. 15 to 18 show a sixth embodiment of the present invention. FIG. 15 is a view showing the overall structure of a remote control device for a water smoothing moving glass window. FIG. 4 is a diagram showing a structure near an upper actuator.

The remote control device 1 for a water smooth moving glass window of this embodiment is arranged so that the water smooth moving glass window 3 mounted on the front surface of the display case 2 is automatically remote-controlled to move it to the front side or the rear side. As well as a direction moving device,
It is a left-right moving device that moves the water smoothing glass window 3 to the left or right in the horizontal direction orthogonal to the front-back direction. The remote control device for a water smoothing glass window 1 includes an upper glass window supporting unit 8 (see FIG. 16) that supports the upper end of the water smoothing glass window 3 of the display case 2 and the water smoothing glass window 3 in the front-back direction. And an electrically operated water-smooth moving glass window opening / closing auxiliary device 500 for moving in the left-right direction.

The display case 2 includes two water-smooth moving glass windows 3, a fixed glass window 4, a lower window frame unit (not shown),
It is composed of an upper window frame unit 6 and left and right upright units (not shown). The water smoothing glass window 3
The trolley type moving body includes a flat glass 400, a lower side frame (not shown) that holds the lower part of the flat glass 400, and a U-shaped upper side frame 401 that holds the upper part of the flat glass 400. have. And the upper side frame 401 is
Flat glass 400 through caulking material (filler) 402
Holding the top of.

A flat plate-like connecting member 403 extended to the front side (right side in the drawing) is fixed to the upper end surface of the upper side frame 401 by tightening or welding. This connecting member 403
A metal or resin roller 404 is rotatably supported at the tip of the roller. The roller 404 is a lower end portion 406 of the upper side cover 405 of the upper side window frame unit 6.
Is loosely fitted in the trough-shaped member 407 fixed to the upper end surface of the member by tightening or welding. This gutter-shaped member 407 is at least the sum of the width of one water smooth moving glass window 3 and the width of one fixed glass window 4 adjacent to the water smooth moving glass window 3,
The water smooth moving glass window 3 is extended in the left-right direction (horizontal direction) orthogonal to the front-back direction.

Further, on the upper end surface of the upper side frame 401 different from the mounting position of the connecting member 403, two mounting fittings 408 are fixed by a predetermined distance by tightening or welding. The two mounting brackets 408 have a U-shaped cross section, and the arm-shaped bracket (arm portion) 409 has a bolt 410.
It is fixed by tightening. At the upper end of the arm-shaped metal fitting 409, a suspension wheel 411 for movably moving in the left-right direction in a state where the water smoothing glass window 3 is hung downward so as to stand upright like a trolley or a ropeway is rotatably attached. There is. The suspension wheel 411 is attached to the upper end of the arm-shaped metal fitting 409 via a rotary shaft 412, and
A washer 413 is mounted between the upper end of the shaft 9 and the upper end of the shaft 9 to facilitate rotation.

A lip seal 415 is mounted between the upper frame 401 and the lower end 415 of the upper window frame 414 of the upper window frame unit 6. Lip seal 41
5 is held at the front end of the lower end portion 415, has a sealing function of making the upper and lower spaces airtight, and when the water smoothing glass window 3 is returned to a fixed position, the water smoothing glass window 3 has an upper side window frame 414.
It has a damper function to soften the impact when it collides with.

The upper glass window supporting unit 8 is a wing supporting means of the present invention, and is provided in the upper window frame 414 of the upper window frame unit 6 so as to be movable in the front-rear direction.
It has a through metal fitting 416 extending in the left-right direction, an upper guide member 417 fixed to the through metal fitting 416 by tightening or welding. The through metal fitting 416 is fixed to the upper cover 405 of the upper window frame unit 6 by tightening or welding together with the upper guide member 417 via a flat plate-shaped mounting member 418 and a ladle-shaped mounting metal member 419. The upper guide member 417 is the horizontal guide means of the present invention, and is a suspension wheel 41 of the water smoothing glass window 3 at the lower end.
It has two rail portions 420 with which 1 is engaged.

Electric water smooth moving glass window opening / closing auxiliary device 5
00 is the operation box 510 and the signal transmission lines 521 and 52.
The second and first and second electric drive devices 530 and 540 are provided. The operation box 510 is the first or second embodiment of the present invention.
The remote operation unit is a remote operation unit in which a microcomputer 560 is built in, and a self-reset type open button 511 and a self-reset type close button 512 are installed on the surface. The open button 511 is an operation signal output unit that outputs an operation signal for instructing to open the water-smooth moving glass window 3 from the home position only while the operator keeps pressing the button.

The closing button 512 is an operation signal output means for outputting an operation signal for instructing the water-smooth moving glass window 3 to return to the home position only while the operator keeps pressing it. The operation box 510 is replaced with a remote controller which is a radio device (transmitter), and receivers are attached to the first and second electric drive devices 530 and 540, and the signal transmission line 52
You may abolish 1,522. Signal transmission lines 521, 52
Reference numeral 2 is a signal transmission unit (command transmission unit) that transmits an operation signal from the microcomputer 600 to the first and second electric drive devices 530 and 540.

The first electric drive device 530 is the first actuator of the present invention, and constitutes an electric actuator together with the two upper side actuators 531 and the geared cable 532 in the main pipe (not shown). It is a thing. The first electric drive device 530 has a first gear device and a first electric motor (DC electric motor or AC electric motor) 533 built therein, and an operating voltage is supplied from a power supply circuit 550. The first electric drive device 530 pushes out, pulls back, or stops the movement of the geared cable 532 in the main pipe based on the operation signal from the microcomputer 600.

The two upper-side actuators 531 are upper-side driving means and push-pull means for moving the water-smooth moving glass window 3 in the front-rear direction, and are circular connected to the main pipe via a joint (not shown). Pipe 534,
It is composed of a case 536 in which the chain 535 appears and disappears from the inside, a bracket 537 for attaching the case 536, and the like. The geared cable 532 in the main pipe is slidably inserted in the circular pipe 534.

A flat plate-shaped connecting piece 538 is integrally attached to the tip of the chain 535. The connecting piece 538 is fastened and fixed to the shoji metal fitting 539 by using a fastener such as a screw. The shoji metal fitting 539 is fastened and fixed to the rear surface of the through metal fitting 416 of the upper glass window support unit 8 and the rear surface of the upper guide member 417 by using fasteners such as screws.

The case 536 is fastened and fixed to the lower end surface of the bracket 537 by using fasteners such as bolts. In this case 536, there are provided a pushing means for pushing the upper side glass window supporting unit 8 forward by pulling back the chain 535, and a pulling back means for pulling back the upper side glass window supporting unit 8 backward by pushing the chain 535. Built-in. Bracket 537
Are fastened and fixed to the upper end portion 421 of the upper window frame 414 of the upper window frame unit 6 using fasteners such as bolts.

The second electric drive unit 540 is the second actuator of the present invention, and comprises a plurality (for example, two) of runners (moving bodies) 541 and a geared cable 542 in a main pipe (not shown). Together with this, it constitutes an electric actuator. Second electric drive device 5
The second gear device 40 has a second gear device and a second electric motor (DC motor or AC motor) 543 built therein, and operates when the operating voltage is supplied from the power supply circuit 550.

The runner 541 has a substantially U-shaped cross section and slides around the guide rail 544. The claw portion 545 of the runner 541 is connected to the geared cable 542. The guide rail 544 has an L-shaped mounting bracket 546 fixed to the front surface of the rail portion 420 of the upper side guide member 417 by welding or the like by a lower end surface. Below the mounting bracket 546, the arm-shaped bracket 4
An L-shaped receiving fitting 547 that is fastened and fixed to 09 is provided.

Next, a microcomputer 560 for controlling the electrically driven water-smooth moving glass window opening / closing auxiliary device 500 will be described with reference to FIGS. This microcomputer 560 is the opening / closing control means of the present invention, and is based on the output signals from the operation box 510 and the first to fourth limit switches (contact position sensors) 561 to 564, and the first and second electric motors. Type drive devices 530, 5
It is a control device that controls 40.

The first limit switch 561 is the first position detecting means of the present invention and is installed at the fixed position A of the horizontal glass window 3 and detects that the water smoothing moving glass window 3 has reached the fixed position A. At this time, the fixed position signal is sent to the microcomputer 56.
Output to 0. The second limit switch 562, which is the second position detecting means of the present invention, is installed at the forward movement completion position B1 of the water smoothing glass window 3 and detects that the water smoothing glass window 3 has reached the forward movement completion position B1. At this time, the forward completion position signal is output to the microcomputer 560.

The third limit switch 563, which is the third position detecting means of the present invention, is installed at the left slide completion position B2 of the water smoothing moving glass window 3, and the water smoothing moving glass window 3 is at the same position as the forward completion position. When it is detected that the left slide completion position B2 is reached, a left slide completion position signal is output to the microcomputer 560. The fourth limit switch 564 is the fourth position detecting means of the present invention,
Installed at the right slide completion position C of the water smoothing glass window 3,
When it is detected that the water smoothing glass window 3 has reached the right slide completion position C, a right slide completion position signal is output to the microcomputer 560. In place of the first to fourth limit switches 561 to 564, a contact position sensor (contact position detecting means) such as a micro switch or a touch switch, or a non-contact position sensor (non-contact) such as a proximity switch or a photoelectric switch. Position detection means) may be used.

Here, the operation of the microcomputer 560 will be described with reference to the explanatory view of FIG. 17 and the flow chart of FIG. Note that the flowchart of FIG. 18 starts the operation when the operating voltage is supplied to the microcomputer 560 from the power supply circuit 550. First, it is determined whether or not the open button 511 of the operation box 510 is pressed (step S1). If the determination result of step S1 is Yes, it is determined whether or not the second limit switch 562 detects the water smoothing moving glass window 3. That is, it is determined whether or not the water-smooth moving glass window 3 has reached the forward movement completion position B1 (see FIG. 17) (step S2). If the determination result in step S2 is No, the first electric motor 53 of the first electric drive device 530 is
3 is energized (normal rotation) to advance the water smoothing moving glass window 3 (step S3). Then return.

If the decision result in the step S2 is Yes, the energization of the first electric motor 533 of the first electric drive device 530 is stopped (step S4), and the fourth limit switch 564 causes the water smoothing glass window to operate. It is determined whether or not 3 is detected. That is, it is determined whether or not the water-smooth moving glass window 3 has reached the right slide completion position C (see FIG. 17) (step S5). The determination result of step S5 is N
In the case of o, the second electric motor 543 of the second electric drive unit 540 is energized (normal rotation) to slide the water smoothing moving glass window 3 to the right (step S6). Then return. If the determination result of step S5 is Yes, the second electric motor 543 of the second electric drive device 540 is
To stop energizing (step S7). Then return.

If the determination result in step S1 is No, it is determined whether or not the closing button 512 of the operation box 510 is pressed (step S8). If the determination result in step S8 is No, the process returns.
If the determination result in step S8 is Yes, it is determined whether the third limit switch 563 detects the water smoothing glass window 3. That is, the water smoothing glass window 3
Has reached the left slide completion position B2 (see FIG. 17) (step S9). If the determination result in step S9 is No, the second electric drive device 540
The second electric motor 543 is energized (reverse rotation) to slide the water smoothing glass window 3 to the left (step S10). Then return.

If the result of the determination in step S9 is Yes, the power supply to the second electric motor 543 of the second electric drive unit 540 is stopped (step S11), and the first limit switch 561 causes the water smoothing glass window to operate. It is determined whether or not 3 is detected. That is, it is determined whether or not the water-smooth moving glass window 3 has reached the fixed position A (see FIG. 17) (step S12). If the determination result in step S12 is No, the first electric motor 5 of the first electric drive device 530
33 is energized (reverse rotation) to retract the water smooth moving glass window 3 (step S13). Then return. If the result of the determination in step S12 is Yes, the energization of the first electric motor 533 of the first electric drive device 530 is stopped (step S14). Then return.

As described above, in the water-smooth moving glass window remote control device 1 of this embodiment, the front surface of the entire display case 2 is the same surface, and the water-smooth moving glass window 3 is at a height beyond the reach of a person. Even if it is one, simply press and hold the open button 511 or the close button 512 of the operation box 510,
The water-smooth moving glass window 3 can be moved forward and rightward, or leftwardly and backwardly while standing upright. Therefore, the burden on the operator is very light.

[Seventh Embodiment] FIGS. 19 to 23 show a seventh embodiment of the present invention.
Is a diagram showing a main part of the second electric drive device, and FIG. 22 is a diagram showing a structure in the vicinity of the second electric motor.

Second electric drive system 600 of this embodiment
Is a second actuator of the present invention, wherein one second actuator
It is composed of an electric motor 601, a geared cable 603 that slides reciprocally in the guide rail 602, and two runners (moving bodies) 604 that are respectively coupled to the geared cable 603.

The second electric motor 601 is fixed by caulking or the like to a mounting stay 611 mounted on an upper guide member (not shown) of the upper glass window supporting unit. The mounting stay 611 includes the mounting brackets 612 and 61.
3 is fastened and fixed to the No. 3 using fasteners 614 and 615 such as screws. 616 is a protective cover. A rotary shaft (not shown) of the second electric motor 601 is drivingly connected to a gear device (not shown) built in the housing 605. The output shaft of the gear device is drivingly connected to a gear 606 that meshes with one geared cable 603.

The guide rail 602 extends in the horizontal direction (horizontal direction) orthogonal to the front-back direction of the water smoothing glass window (not shown), and as shown in FIG. 20, the second electric motor 601. In the vicinity of (center), it is held in a state of being sandwiched between the mounting stay 611 and the mounting bracket 612. Also, on both sides of the guide rail 602, as shown in FIG.
As shown in FIG.
It is fixed by tightening with 8. The guide plate 617
Is a mounting bracket 61 using a fastener 619 such as a screw.
It is clamped and fixed to 2.

The two runners 604 are connected to, for example, the arm-shaped metal fittings 409 of the suspension wheel 411 of the sixth embodiment, and are fixed to one geared cable 603, respectively. These runners 604 are connected to the second electric motor 6
When 01 is energized and the gear 606 is rotationally driven, one geared cable 603 moves in the left-right direction, so that the insertion hole 6 formed in one end surface of the guide rail 602.
While passing through 07, it moves in the horizontal direction (horizontal direction) orthogonal to the front-back direction of the water smoothing glass window (not shown). 608 and 609 are special pipes and main pipes on which the geared cable 603 slides, and 610 is a joint portion connecting the special pipes 608 and the main pipes 609.

[Modification] In this embodiment, the present invention is applied to the remote control device 1 for the water smoothing glass window of the display case. However, the present invention is applied to the water smoothing glass window of the display case and the clothes case, the greenhouse, and the vehicle. It may be applied to a remote control device for a door and a window. It may be applied to a remote control device for opening / closing doors of airplanes, ships, and bus vehicles. As the actuator, not only a mechanical actuator but also an electric actuator such as an electric motor, a magnetic actuator such as an electromagnetic motor, and a fluid pressure actuator such as a hydraulic motor or a negative pressure servo motor may be used. A transmission means such as a shaft, a belt or a sprocket may be interposed between the actuator and the wing support means.

[Brief description of drawings]

FIG. 1 is a perspective view showing an outline of the entire structure of a remote control device for a water smoothing moving glass window (first embodiment).

FIG. 2 is a front view showing a display case (first embodiment).

FIG. 3 is a cross-sectional view showing a structure near a handle (first embodiment).

FIG. 4 is a vertical sectional view showing a structure near a handle (first embodiment).

FIG. 5 is an exploded view showing the lower structure of the display case (first embodiment).

FIG. 6 is a vertical cross-sectional view showing a structure near a lower actuator (first embodiment).

FIG. 7 is a vertical cross-sectional view showing the structure in the vicinity of a lower guide unit (first embodiment).

FIG. 8 is an exploded view showing the upper structure of the display case (first embodiment).

FIG. 9 is a vertical cross-sectional view showing a structure near an upper actuator (first embodiment).

FIG. 10 is a vertical cross-sectional view showing the structure in the vicinity of the lower guide unit (first embodiment).

FIG. 11 is a perspective view showing a lower end structure of a water smoothing glass window (second embodiment).

FIG. 12 is a schematic view showing an electrically operated opening / closing assisting device for a water smoothing moving glass window (third embodiment).

FIG. 13 is a cross-sectional view showing a display case (fourth embodiment).

FIG. 14 is a cross-sectional view showing a display case (fifth embodiment).

FIG. 15 is a schematic view showing the overall structure of a remote control device for a water smoothing moving glass window (sixth embodiment).

FIG. 16 is a vertical sectional view showing a structure near an upper actuator (sixth embodiment).

FIG. 17 is an explanatory view showing the operation of an electrically operated opening / closing assisting device for a water smoothing glass window (sixth embodiment).

FIG. 18 is a flowchart showing the operation of the microcomputer (sixth embodiment).

19A is a plan view showing a main part of a second electric drive device, and FIG. 19B is a side view showing a main part of the second electric drive device (seventh embodiment). .

FIG. 20 is a sectional view taken along line XX of FIG. 19A (seventh embodiment).

FIG. 21 is a sectional view taken along line YY of FIG. 19B (seventh embodiment).

FIG. 22 is a front view showing a structure near a second electric motor (seventh embodiment).

[Explanation of symbols]

1 Remote control device for water smooth moving glass window (remote control device for slide wing) 2 Exhibition case 3 Water smooth moving glass window (slide wing) 4 Fixed glass window (upright wall) 7 Lower glass window support unit (wing support means) 8 Upper Glass Window Support Unit (Wing Support Means) 9 Water Smoothing Glass Window Opening / Closing Aid Device 52 Lower Guide Rail (Horizontal Guide Means) 56 Upper Guide Rail (Horizontal Guide Means) 60 Remote Control Unit (Remote Operation) Means) 61 Handle (rotary type manual operation means) 70 Transmission unit (remote operation means) 71 Turning box (turning part) 100 Lower side drive unit 110 Lower side actuator 120 Lower side induction unit (front-back direction guiding means) 200 Upper side Drive unit 210 Upper actuator 220 Upper guidance unit (front and rear Direction guidance means) 300 Electric water opening / closing auxiliary device for water smoothing glass window 310 Operation box (remote operation part) 311 Open switch (operation signal output means) 312 Closure switch (operation signal output means) 313 Stop switch (operation signal output means) ) 321 signal transmission line (command transmission unit, signal transmission unit) 322 signal transmission line (command transmission unit, signal transmission unit) 330 electric drive device (actuator) 340 electric drive device (actuator) 500 electric water smoothing glass Window opening / closing auxiliary device 510 Operation box (first and second remote operation parts) 511 Open button (operation signal output means) 512 Closure button (operation signal output means) 521 Signal transmission line (command transmission part, signal transmission means) 522 Signal transmission line (command transmission unit, signal transmission means) 530 First electric drive device (first actuator 532 geared cable 533 first electric motor 540 second electric drive device (second actuator) 541 runner (moving body) 542 geared cable 543 second electric motor 544 guide rail 560 microcomputer (opening / closing control means) 561 first Limit switch (first position detecting means) 562 Second limit switch (second position detecting means) 563 Third limit switch (third position detecting means) 564 Fourth limit switch (fourth position detecting means) 600 Second electric type Drive device (second actuator) 601 Second electric motor 602 Guide rail 603 Geared cable 604 Runner (moving body)

Claims (16)

[Claims] 1. A slide wing arranged upright, (b) a wing support means for supporting the slide wing in an upright state, and (c) the wing support means fore and aft of the slide wing. A remote operation device for a slide wing, comprising an actuator for moving the actuator in a direction, and (d) remote operation means for remotely operating the actuator. 2. The remote control device for slide wings according to claim 1, wherein the wing support means guides the slide wings so as to be movable in a horizontal direction orthogonal to the front-rear direction. A remote control device for a slide wing, characterized by comprising means. 3. The remote control device for slide wings according to claim 2, wherein upright wall bodies arranged upright are arranged in parallel next to the slide wings. Remote control device. 4. The remote operation device for slide wings according to claim 3, wherein one end surface of the slide wing is arranged on substantially the same plane or substantially the same curvature surface as the wall surface of the upright wall body. Remote control device for slide wings. 5. The remote operation device for slide wings according to claim 3 or 4, wherein the upright wall body is a water smooth motion wing capable of seeing through the inside. . 6. The remote control device for a slide wing according to claim 1, wherein the wing support means supports and guides the wing support means so as to move in the front-rear direction. A remote control device for a slide wing, which is provided with. 7. The remote operation device for a slide wing according to claim 1, wherein the slide wing is a water smooth motion wing capable of seeing through the inside. Operating device. 8. The remote operation device for slide wings according to claim 1, wherein the remote operation means issues a command to move the wing support means in the front-rear direction. And a command transmission unit for transmitting a command from the remote operation unit to the actuator, a remote operation device for slide wings. 9. The remote operation device for slide wings according to claim 8, wherein the remote operation part is a manually operated rotary manual operation means, and the command transmission part is a rotation of the manual operation means. A remote operation device for a slide wing, comprising: a turning portion that turns the movement into a reciprocating movement in the axial direction, and a cord body that connects the turning portion and the actuator. 10. The remote operation device for slide wings according to claim 8, wherein the remote operation section is operation signal output means for outputting an operation signal instructing to move the wing support means in the front-rear direction. The remote control device for slide wings, wherein the command transmission unit is a signal transmission unit that transmits an operation signal from the operation signal output unit to the actuator. 11. The remote operation device for slide wings according to claim 9, wherein the remote operation means has a state holding means for holding a state of the actuator. 12. The remote control device for a slide wing according to claim 1, wherein the actuator pushes the wing support means forward or rearward, and the wing support means. A remote control device for a slide wing, comprising a pulling back means for pulling back the rear side or the front side. 13. (a) Upright slide wings, and (b) horizontal guide means for guiding the slide wings so as to be movable in a horizontal direction orthogonal to the front-rear direction. A wing support means for supporting the slide wing in an upright state; (c) a first actuator for moving the horizontal guide means in the front-rear direction of the slide wing; (d) a horizontal wing for the slide wing. A remote operation device for a slide wing, comprising: a second actuator that horizontally moves along a direction guide means; and (e) a remote operation means that remotely operates the first actuator and the second actuator. 14. The remote operation device for slide wings according to claim 13, wherein the remote operation means commands a first remote operation unit to move the slide wing from a fixed position, and the slide wing is moved to a fixed position. Second remote control unit for instructing to return to the first position, first position detecting means for detecting that the slide wing has reached a fixed position, second position detecting means for detecting that the slide wing has reached the forward completion position Third position detecting means for detecting that the slide wing has reached a horizontal one side completion position that is the same position as the forward movement completed position, and that the slide wing has reached the other horizontal side completion position. Fourth position detecting means for detecting, the first and second remote operation units, and the first to fourth
A remote operation device for a slide wing, comprising an opening / closing control means for controlling the first actuator and the second actuator according to the output of the position detection means. 15. The slide wing remote control device according to claim 13 or 14, wherein the first actuator is an electric motor attached to the wing support means. Remote control device for wings. 16. The slide wing remote control device according to claim 13 or 14, wherein the second actuator is an electric motor attached to the wing support means. Remote control device for wings.