JP2020122341A - Roll-up system - Google Patents

Abstract

To provide a roll-up system capable of carrying out attachment/detachment of a connector and a wiring in a simple and safe manner.SOLUTION: A roll-up system 60 for rolling up an opening/closing body 30 for opening/closing an opening 3 of a building, via an opening/closing machine 50 comprises: a drive part 61 connected to an input shaft of the opening/closing machine 50, for electrically driving the opening/closing machine 50; and a first connector 62 provided on an exterior of a storage part 10 that stores the opening/closing body 30, and mounted on a drive-side wiring 4 connected directly or indirectly relative to the drive part 61, for attachably/detachably connecting a power supply side wiring 5 connected directly or indirectly relative to a power supply unit 69 that supplies electric power to the drive part 61. The first connector 62 is disposed in a workable position H1 that allows an operator positioned on a floor face 9a of the building to carry out attachment/detachment of the first connector 62 and the power supply side wiring 5.SELECTED DRAWING: Figure 1

Description

The present invention relates to a winding system.

BACKGROUND ART Conventionally, an opening provided in a wall of a building or the like is provided with a fireproof shutter that closes the opening as a disaster prevention means for preventing the spread of fire when a fire occurs. In this fire prevention shutter, a manual fire prevention shutter is often used because it is not necessary to lower the shutter curtain only when a fire occurs and it is not necessary to lower it frequently. For such a fireproof shutter, inspection work is regularly performed to confirm that the shutter curtain can be normally lowered when a fire occurs. In this inspection work, after closing the opening with the shutter curtain, the shutter curtain is wound up in order to wind up the shutter curtain and return to the initial state. However, in the manual fireproof shutter as described above, it is necessary to wind up the shutter curtain manually, which requires a great deal of labor for the operator. In particular, when the length (height) in the opening/closing direction of the shutter is relatively high or the number of shutters to be inspected is large, it is a great burden for the operator to perform the winding operation manually. ..

Therefore, in order to reduce the burden on such an operator, for example, a drive unit that is detachably connected to a rotary shaft of an opening/closing machine that constitutes a fireproof shutter is provided inside a shutter housing portion that constitutes a fireproof shutter. A drive unit for electrically driving the switch, and a fixing unit that detachably fixes the drive unit to the housing of the switch in a state where the switch and the drive are arranged in parallel in a horizontal direction, An operation unit that is connected to a commercial power supply via wiring outside the shutter storage unit, and is electrically connected to the drive unit inside the shutter storage unit via a wiring and a connector inside the shutter storage unit. And a control unit that includes a control unit that winds the shutter curtain based on the presence or absence of an input of a hoisting signal that is received via the operation unit. See Patent Document 1). Further, the connector is a connector arranged inside the shutter housing portion, and a connector for detachably connecting the wiring protruding from the control unit and the wiring located on the operation portion side, and the shutter housing portion. The connector is disposed outside the operation unit at a position higher than the operation unit, and includes a connector that detachably connects the wiring located on the operation unit side and the wiring protruding from the operation unit. According to such a hoisting device, since the worker can perform the hoisting work while being on the floor surface, the hoisting work can be easily performed.

JP, 2016-194194, A

However, in the above conventional winding device, as described above, since the connector is arranged inside the shutter housing portion and the connector is arranged outside the shutter housing portion above the operation portion, for example, the control unit When performing the work of connecting the control unit and the operation unit using the wiring and the connector in the state where the is placed inside the shutter housing part, the worker performs the work at a peripheral position of the shutter housing part or a position in the vicinity thereof. Since it is necessary to perform the work at a high position like above, it may be difficult to ensure the safety of the worker. Therefore, there is room for improvement from the viewpoint of safety of the above work.

An object of the present invention is to solve the above problems in the prior art, and it is an object of the present invention to provide a hoisting system that enables easy and safe attachment/detachment work of a connector and wiring.

In order to solve the above problems and to achieve the object, a hoisting system according to claim 1 is a hoisting system for hoisting an opening/closing body for opening and closing an opening of a building through a switch. A drive means connected to a rotary shaft of the switch, the drive means for electrically driving the switch, and the drive means provided outside the storage means for storing the switch. A connector attached to a drive-side wiring that is directly or indirectly connected to the drive-side wiring, the power-side wiring that is directly or indirectly connected to the power-supply means supplying electric power to the drive means is detachably connected. And a connector for the purpose of arranging the connector at a position where an operator located on the floor surface of the building can attach and detach the connector and the power supply side wiring.

The winding system according to claim 2 is the winding system according to claim 1, wherein the connector is provided on a portion of a skeleton of the building located in the vicinity of the opening, the portion being above the floor surface. It was attached directly or indirectly.

A winding system according to a third aspect is the winding system according to the first or second aspect, further comprising connector housing means for housing the connector.

The winding system according to claim 4 is the winding system according to any one of claims 1 to 3, wherein the operating means receives an input of a winding signal for instructing winding of the opening/closing body by driving the driving means. And a control means electrically connected to the operating means, the control means controlling the drive means based on whether or not the hoisting signal is input by the operating means. Includes a first power supply side wiring located on the connector side and a second power supply side wiring located on the power supply means side, and the control means and the connector are mutually connected via the first power supply side wiring. The power source side wiring, the operating means, and the control means can be conveyed by connecting the power source side wiring to the control means and the power source means via the second power source side wiring.

The hoisting system according to claim 5 is the hoisting system according to any one of claims 1 to 3, wherein the hoisting system is provided outside the housing means and electrically connected to the connector. An operating means for receiving an input of a hoisting signal for instructing the hoisting of the opening/closing body by driving of the driving means, and the presence or absence of the input of the hoisting signal provided outside or inside of the accommodating means. Control means for controlling the drive means based on the above, wherein the drive side wiring includes a first drive side wiring located on the connector side and a second drive side wiring located on the drive means side. By connecting the control means and the connector to each other via the first drive side wiring, and connecting the control means and the drive means to each other via the second drive side wiring, The operation means and the control means can be installed in the body of the building or the storage means.

The winding system according to claim 6 is the winding system according to any one of claims 1 to 3, wherein the opening/closing device is an electrically operated opening/closing device controlled by a first controller. Operation means for receiving an input of a hoisting signal for instructing hoisting of the opening/closing body by driving the means, and second control for controlling the drive means based on the presence or absence of the input of the hoisting signal received by the operation means The second control means gives an instruction to stop the control of the opening/closing device by the first control means when the input of the hoisting signal by the operating means is accepted. A stop signal is output to the first control means.

A winding system according to a seventh aspect is the winding system according to any one of the first to sixth aspects, wherein the power supply means is a commercial AC power source of 100V.

According to the hoisting system of claim 1, the connector is attached to the drive side wiring that is provided outside the housing means and is directly or indirectly connected to the drive means, and supplies electric power to the drive means. A connector for detachably connecting the power supply side wiring directly or indirectly connected to the power supply means for supply is provided, and the connector located between the connector and the power supply side wiring is provided by an operator located on the floor surface of the building. Since it is arranged at a position where attachment/detachment work can be performed, the attachment/detachment work can be performed while the worker is on the ground, and the conventional technique (the connector is arranged inside the shutter housing portion and the connector is arranged outside the shutter housing portion). Compared to the technique (arranged above the operation unit), the worker does not need to perform the attaching/detaching work in the vicinity of the storage means, and thus the attaching/detaching work can be performed easily and safely.

According to the hoisting system of claim 2, the connector is directly or indirectly attached to a portion of the building body located in the vicinity of the opening, which is above the floor surface. The connector can be stably attached while maintaining workability.

According to the hoisting system of the third aspect, since the connector accommodating means for accommodating the connector is provided, the connector can be accommodated in the connector accommodating means. Therefore, it is possible to prevent the connector from being exposed from the outside, so that it is easy to avoid accidentally touching the connector by a third party when the connector is permanently installed, for example.

According to the hoisting system of claim 4, the operating means and the control means electrically connected to the operating means are provided, and the control means and the connector are mutually connected via the first power source side wiring. At the same time, by connecting the control means and the power supply means to each other via the second power supply side wiring, the power supply side wiring, the operating means, and the control means can be carried. Therefore, the power supply side wiring, the operating means, and the control The means can be transported together. Therefore, for example, in a case where a plurality of opening/closing devices, an opening/closing device, a driving means, a connector, and a switching device including a driving side wiring are installed in a building, one set including a power side wiring, an operating means, and a control means By simply preparing this, the opening/closing body of each opening/closing device can be wound using this set, and the installation cost of the winding system can be easily reduced.

According to the hoisting system of claim 5, there is provided an operation means provided outside the storage means and electrically connected to the connector, and a control means provided outside or inside the storage means, By connecting the control means and the connector to each other via the first drive side wiring and connecting the control means and the drive means to each other via the second drive side wiring, the operation means and the control means are connected to each other. Since it can be installed in the skeleton or the storage means, the drive side wiring, the operating means, and the control means can be installed together in the skeleton or the storage means. Therefore, it is not necessary to carry the control means and the operation means when performing the attachment/detachment work, so that it is easier to improve the efficiency of the attachment/detachment work as compared with the case where the operation means and the control means are connected using the power supply side wiring. Become.

According to the hoisting system of claim 6, the opening/closing device is an electrically operated opening/closing device controlled by the first control means, and the operation means receives the input of the hoisting signal and the operation means receives the hoisting signal. Second control means for controlling the driving means based on the presence or absence of the input of the hoisting signal, and when the second control means accepts the input of the hoisting signal by the operating means, the stop signal is issued. Since the signal is output to the first control means, compared with the case where the stop signal is not output, the control of the opening/closing device by the first control means and the control of the drive means by the second control means are performed at the same time to open/close the switch. Failure of the machine or the drive means can be avoided.

According to the hoisting system of claim 7, since the power supply means is a commercial AC power supply of 100 V, it is relatively easy to secure electric power as compared with other power supply means, and thus the usability of the hoisting system is easily improved. Become.

It is a front view which shows notionally the switchgear which concerns on Embodiment 1 of this invention (illustration is partially omitted). It is a figure which shows the peripheral region of the storage part of FIG. 1 (a part illustration is abbreviate|omitted). FIG. 3 is a sectional view taken along the line AA of FIG. It is a front view which shows the connector storage part in the state which closed the lid part. 7 is a flowchart of a winding process according to the first embodiment. It is a front view which shows notionally the switchgear concerning Embodiment 2 (a part of illustration is abbreviate|omitted). It is a front view which shows the connector storage part in the state which closed the lid part. It is a front view which shows notionally the switchgear which concerns on Embodiment 3 (a part of illustration is abbreviate|omitted). 9 is a flowchart of a winding process according to the third embodiment.

An embodiment of a winding system according to the present invention will be described in detail below with reference to the accompanying drawings. First, the basic concept of the [I] embodiment will be described, then the specific contents of the [II] embodiment will be described, and finally, a modified example of the [III] embodiment will be described. However, the present invention is not limited to the embodiments.

[I] Basic Concept of Embodiment First, the basic concept of the embodiment will be described. The embodiment generally relates to a hoisting system for hoisting an opening/closing body for opening and closing an opening of a building through a switch.

Here, the “building” is a concept including, for example, a detached house, a collective housing such as an apartment or a condominium, an office building, a commercial facility, a public facility, etc., although its specific structure and type are arbitrary. .. Further, the "building opening" is an opening formed in a part of the building body (for example, a wall, a ceiling, or a floor) for installing a window or an entrance. Further, the "opening/closing device" including the opening/closing body, the opening/closing device, and the winding system is a device attached to an opening of a building for crime prevention and fire prevention, and includes, for example, a heavy shutter, a lightweight shutter, a window shutter, and a pipe. It is a concept including a shutter and the like. Also, the opening/closing structure of the opening/closing device is arbitrary, and can be configured as, for example, a “vertical opening/closing device”, a “left/right opening/closing device”, or the like. Further, the drive system of the switchgear is arbitrary, and for example, "manual switchgear", "motorized switchgear", etc. are applicable. Hereinafter, in Embodiments 1 and 2, a case will be described in which the opening/closing device is a shutter device of a vertical opening/closing type and a manual type provided on the outer wall of a building such as a commercial facility, and in Embodiment 3, the opening/closing device is A case will be described in which the shutter device is an electric shutter device that is provided on the outer wall of the building and is opened and closed.

[II] Specific Contents of Embodiment Next, specific contents of the embodiment will be described.

[Embodiment 1]
First, the winding system according to the first embodiment will be described. In the first embodiment, the opening/closing device is a manual shutter device, and is provided with a winding-up side control unit described later connected to a power supply side wiring described below.

(Constitution)
First, the configuration of the opening/closing device to which the winding system according to the first embodiment is applied will be described. In the following description, the X direction in FIG. 1 is the left-right direction of the switchgear (−X direction is the left side of the switchgear, +X direction is the right side of the switchgear), and the Y direction of FIG. 3 is the front-rear direction of the switchgear (+Y). The direction is the front of the switchgear (outdoor side of the building), the -Y direction is the rear of the switchgear (indoor side of the building), and the Z direction of FIG. 1 is the vertical direction of the switchgear (+Z direction). The upward direction of the switchgear and the -Z direction are referred to as the downward direction of the switchgear).

As shown in FIGS. 1 to 3, the opening/closing device 1 schematically includes a storage section 10, a guide rail 20, an opening/closing body 30, a winding shaft 40, a drive side bearing section 41, and a driven side bearing section (not shown). , A switch 50, an automatic closing device (not shown), a manual closing device (not shown), and a hoisting system 60. However, the description of the structure of the switchgear 1 not described is omitted because it is the same as the conventional one.

(Structure-storage section)
Returning to FIG. 1, the storage section 10 is a storage means for storing the opening/closing body 30. The storage unit 10 is configured using, for example, a ceiling-receptive storage case (or may be an exposed-retention storage case), and specifically, is formed of a hollow steel body. As shown in FIGS. 1 to 3, it is installed above the upper end of the opening 3 in the building (specifically, installed above the ceiling 9b of the building). In addition, the winding shaft 40 is stored inside the storage unit 10, and at least a part of the opening/closing unit 30 is also stored in the storage unit 10 when the opening/closing unit 30 is wound up by the winding shaft 40. It is stored inside.

Further, as shown in FIGS. 2 and 3, the housing portion 10 includes a drive side bearing plate 11, a drive side mounting piece 12, a driven side bearing plate 13, a driven side mounting piece (not shown), and a case plate 14. I have it.

(Structure-Housing-Drive bearing plate, drive mounting piece)
The drive side bearing plate 11 is a plate material for covering the left end portion of the storage space of the storage portion 10, and is provided substantially vertically so as to cover the left end portion of the storage space, as shown in FIGS. 2 and 3. It is connected to the drive-side mounting piece 12 by a fixture or the like. The drive-side mounting piece 12 is a plate member for mounting the drive-side bearing plate 11 to the building body 2 (specifically, the outer wall) of the building, and is rearward of the drive-side bearing plate 11 as shown in FIG. Is provided so as to face the skeleton 2, and is connected to the skeleton 2 by a fixture or the like.

(Structure-Housing-Driven bearing plate, Driven mounting piece)
The driven-side bearing plate 13 is a plate material for covering the right end portion of the storage space, and as shown in FIG. 2, it is provided substantially vertically so as to cover the right end portion of the storage space, and is attached to the driven-side mounting piece. Are connected by a fixture or the like. The driven-side mounting piece is a plate material for mounting the driven-side bearing plate 13 to the frame 2, and is provided so as to face the frame 2 behind the driven-side bearing plate 13 and to the frame 2. It is connected by a fixture or the like.

(Structure-Storage-Case plate)
The case plate 14 is a curved plate material for covering the back surface, the upper surface, and the lower surface of the storage space. As shown in FIGS. 2 and 3, the case plate 14 covers the back surface, the upper surface, and the lower surface of the storage space. It is provided and connected to the skeleton 2 by a fixture or the like.

Further, as shown in FIG. 3, a lintel 10a is provided on the ceiling 9b located on the lower side of the storage unit 10 on the outdoor side of the building centered on the opening/closing body 30 and on the indoor side of the building. Since the lintel opening 10b is formed between these lintels 10a over the entire length of the opening 3 in the left-right direction, the opening/closing body 30 is inserted and removed through the lintel opening 10b.

(Structure-guide rail)
Returning to FIG. 1, the guide rail 20 guides the opening/closing body 30 so as to move along the opening/closing direction (vertical direction) of the opening 3. The guide rail 20 is, for example, an elongated body formed to have a substantially U-shaped cross section, and as shown in FIG. It is arranged in the direction along which it is fixed directly to the skeleton 2, or indirectly fixed through a base material (not shown).

(Structure-Opening/Closing body)
The opening/closing body 30 is for opening/closing the opening 3. Specifically, the opening/closing body 30 is moved to be closed or opened by the rotational drive of the winding shaft 40, whereby the state of the opening/closing body 30 is fully opened or fully closed. It can be in the open state or the half open state. The opening/closing body 30 is configured using, for example, a known shutter curtain. Specifically, as shown in FIG. 1, a plurality of slats 31 are provided, and the plurality of slats 31 are mutually connected via fitting portions (not shown) formed at both upper and lower ends of each slat 31. Fitted and connected. Further, each of the left and right ends of the opening/closing body 30 is inserted into the guide rail 20 through the U-shaped open end of the guide rail 20, and the inside of the guide rail 20 in the vertical direction. Is slidable, and is regulated in the front-rear direction so as not to fall outside the guide rail 20. A seat plate 33 is connected to the lower end of the opening/closing body 30. The seat plate 33 is arranged so as to be close to or in contact with the floor surface 9a of the building in the fully closed state, and is formed over the entire length in the left-right direction of the lower end portion of the opening/closing body 30.

(Structure-Winding shaft)
The winding shaft 40 is for opening and closing the opening/closing body 30 (the maximum winding diameter M of the winding shaft 40 is shown in FIG. 3). The winding shaft 40 is configured by using, for example, a known winding shaft, and is installed along the left-right direction as shown in FIGS. 2 and 3. Further, a connecting slat (not shown) connected to the upper end of the opening/closing body 30 is connected to the winding shaft 40. By rotating the winding shaft 40, the opening/closing body 30 is opened via the connecting slat. It can be opened and closed.

Further, as shown in FIG. 2, the winding shaft 40 is provided with a driving side flange portion (not shown) and a driven side shaft portion 40a. Among these, the driving side flange portion is a connecting means for connecting the winding shaft 40 and the driving side bearing portion 41, and is formed of a substantially cylindrical body, and the axial direction of the driving side flange portion is It is arranged along the left-right direction and is connected to the drive-side bearing portion 41 (specifically, the drive-side bearing portion main body described later) by a fixture or the like. The driven-side shaft portion 40a is a connecting means for connecting the winding shaft 40 and the driven-side bearing portion, and is formed of a long rod-shaped body, and as shown in FIG. The axial direction of 40a is arranged along the left-right direction, and is rotatably inserted into the driven-side bearing portion.

(Structure-Drive side bearing)
The drive side bearing portion 41 is a bearing portion for rotatably supporting the winding shaft 40, and includes a drive side bearing portion main body (not shown) and a winding shaft side sprocket 42 as shown in FIG. There is.

Of these, the drive-side bearing portion main body is a basic structure of the drive-side bearing portion 41, and is configured using, for example, a known drive shaft, and is connected to the drive-side flange portion by a fixture or the like. In addition, it is rotatably fixed to the drive side bearing plate 11 by a fitting structure or the like. The take-up shaft side sprocket 42 is for transmitting the rotational driving force from the opening/closing machine 50 to the drive side bearing portion main body via the transmission member 43 (for example, an annular roller chain or the like). The winding shaft side sprocket 42 is configured by using, for example, a known sprocket, and as shown in FIG. 3, an end portion of the drive-side bearing portion main body opposite to the winding shaft 40 side end portion. (Specifically, it is provided at or near the right end of the drive-side bearing portion main body) and is fixed to the drive-side bearing portion main body by a fixture or the like.

(Structure-Driven bearing part)
The driven-side bearing portion rotatably supports the winding shaft 40. The driven-side bearing portion is configured by using, for example, a known bearing member that can rotatably connect the driven-side shaft portion 40a, and the side surface of the driven-side bearing plate 13 on the winding shaft 40 side (specifically, It is provided on the left side surface of the driven bearing plate 13. Specifically, the driven-side shaft portion 40a is arranged in an inserted state, and is fixed to the driven-side bearing plate 13 by a fixing tool or the like.

(Structure-Switch)
Returning to FIG. 1, the opening/closing device 50 is for winding or unwinding the opening/closing body 30. Specifically, the opening/closing body 30 is closed or moved by manually rotating the winding shaft 40. Move it open. The opening/closing device 50 is configured by using, for example, a known manual opening/closing device, and as shown in FIG. 1, it is located outside the storage section 10 in front of the winding shaft 40 and has a drive side bearing. It is provided near the portion 41.

In addition, as shown in FIGS. 2 and 3, the switch 50 includes an input shaft 51, an output shaft 52, a switch side sprocket 53, a switch main body 54, and a manual operation unit 55.

Of these, the input shaft 51 is a rotary shaft for transmitting the rotational driving force to the output shaft 52 via a connecting shaft (not shown). As shown in FIG. 2, the input shaft 51 is arranged such that a part of the input shaft 51 projects outward from the right end portion of the switchgear body 54 and rotates with respect to the switchgear body 54. Fixed as possible. The output shaft 52 is for transmitting the rotational driving force transmitted from the input shaft 51 via the connecting shaft to the winding shaft 40. As shown in FIG. 2, the output shaft 52 is arranged such that a part of the output shaft 52 protrudes outward from the left end portion of the switchgear body 54 and rotates with respect to the switchgear body 54. Fixed as possible. Further, the switch-side sprocket 53 is for transmitting the rotational driving force transmitted from the output shaft 52 to the take-up shaft-side sprocket 42 via the transmission member 43, and as shown in FIG. It is fixed to the left end of 52.

Further, the switch main body 54 is a basic structure of the switch 50, and is fixed to the drive-side bearing portion 41 via a connecting plate 50a by a fixing tool or the like, and includes a speed reducer, a speed governor, and a brake. Parts (both not shown). Of these, the speed reducer is for reducing the rotational speed of the output shaft 52 via the connecting shaft, and is configured using, for example, a known speed reducer. The speed governor is for adjusting the rotational speed of the output shaft 52 via the connecting shaft, and is configured using, for example, a known speed governor. The brake unit is a brake unit for stopping the closing movement of the opening/closing body 30 due to its own weight, and is configured by using, for example, a known brake unit.

Further, the manual operation part 55 is a manual operation means for manually performing a release operation of the brake part. The manual operation part 55 is configured by using, for example, a wire type operation means, and as shown in FIG. 2, a part of the manual operation part 55 is provided so as to be exposed from the switch main body 54 to the outside. In addition, the other part of the manual operation part 55 is connected to the brake part. The opening/closing body 30 can be closed and moved by its own weight by releasing the brake part by manually pulling the manual operation part 55 with the manual operation part 55.

(Structure-Automatic closing device)
The automatic closing device is an automatic brake releasing means that automatically releases the brake part of the opening/closing device 50 to close the opening/closing body 30 by its own weight. For example, the automatic closing device is configured by using a known automatic closing device, etc. It is provided outside 10. Here, “release the brake part of the switch 50” means that the brake part of the switch does not act on the output shaft 52 of the switch 50. Specifically, in the first embodiment, when a fire detection signal is input from a disaster prevention board (not shown), a release lever (not shown) of the opening/closing device 50 is opened and closed by an operation portion (not shown). By opening the brake part of the machine 50, the opening/closing body 30 is closed and moved by its own weight.

(Structure-Manual closing device)
The manual closing device is a manual brake releasing means for manually closing the opening/closing body 30 by manually releasing the brake part of the opening/closing device 50, and for example, a known manual closing device (as an example, a push button type manual closing device). ) And the like, and is provided outside the storage unit 10. Here, "to release the brake part of the opening/closing device 50" specifically means, in the first embodiment, when the first operation is performed via the manual closing device, the release lever of the opening/closing device 50 is operated. The opening/closing body 30 is closed and moved by its own weight by releasing the brake part of the opening/closing device 50 by performing a releasing operation via the part. Further, when the second operation is performed via the manual closing device, the release lever of the opening/closing device 50 is returned to the state before the release operation, thereby causing the brake part of the opening/closing device 50 to operate, and thus the opening/closing body 50 is opened. Stop the closing movement due to its own weight.

(Structure-Hoisting system)
Returning to FIG. 1, the hoisting system 60 is a system for hoisting the opening/closing body 30 via the opening/closing machine 50, and as shown in FIG. 1, the driving section 61, the first connector section 62, and the second connector section 63. , The third connector portion 64, the upper limit detection portion 65, the number of times detection portion 66, the connector storage portion 67, and the winding side control unit 70.

Further, the connecting method of each part constituting the winding system 60 is arbitrary, but in the first embodiment, it is as follows. That is, as shown in FIG. 1, the first connector portion 62 is connected to the drive portion 61 via the wiring 4 (hereinafter, referred to as “drive side wiring 4”) located closer to the drive portion 61 than the first connector portion 62. Is electrically connected to. In addition, the first connector portion 62 is located closer to the power supply portion 69 than the first connector portion 62 is the wiring 5 (hereinafter referred to as “power supply-side wiring 5”), the second connector portion 63, and the third connector portion 64. The winding-up control unit 70 and the power supply unit 69 (in FIG. 1, the power supply unit 69 connected to the wiring 68a of the cord reel 68) are electrically connected via the. Specifically, the power source side wiring 5 is the first power source side wiring 5a located on the side of the first connector portion 62 (specifically, the first power source side wiring 5a protruding from the winding side control unit 70 or the second connector portion 63). Power supply side wiring 5a) and the second power supply side wiring 5b located on the power supply section 69 side (specifically, the second power supply side wiring 5b protruding from the winding control unit 70 or the third connector section 64). The first power supply side wiring 5a and the second connector section 63 are used to mutually connect the first connector section 62 and the winding-side control unit 70, and the second power supply side wiring 5b and the third connector section are also provided. The winding-up control unit 70 and a connector portion (not shown) of the cord reel 68 are mutually connected via 64 (in this case, a lid portion 67b of a connector storage portion 67 described later is open). .. Here, the "power supply unit 69" is a power supply unit that supplies electric power to the drive unit 61, and in the first embodiment, it is configured by using a commercial alternating-current power supply of 100 V, so that it is different from other power supply units. It becomes relatively easy to secure electric power. In addition, the upper limit detection unit 65 is electrically connected to the drive unit 61 via the wiring 6 (hereinafter, referred to as “first detection-side wiring 6”), and the frequency detection unit 66 is not shown in the drawings (hereinafter, referred to as wiring). , "Second detection side wiring"), and is electrically connected to the first connector portion 62.

With the above connection, the winding control unit 70 and each of the drive unit 61, the upper limit detection unit 65, and the number-of-times detection unit 66 can communicate with each other directly or indirectly. Moreover, it becomes possible to directly or indirectly supply the power from the power supply unit 69 to the winding-up control unit 70, the drive unit 61, the upper limit detection unit 65, and the number-of-times detection unit 66. In the first embodiment, the drive-side wiring 4, the first power-source-side wiring 5a, the first detection-side wiring 6, and the second detection-side wiring function not only as signal lines but also as power-source lines. explain. Further, the second power supply side wiring 5b will be described as one that functions only as a power supply line.

(Structure-Hoisting system-Drive unit)
The drive unit 61 is a drive unit that electrically drives the switch 50. The drive unit 61 is configured using, for example, a known drive unit (as an example, a motor for an opening/closing device including a rotation shaft (not shown)), and as shown in FIGS. 1 to 3, the storage unit 61. It is provided outside the switch 10 at a position near the switch 50.

The method of installing the drive unit 61 is arbitrary, but in the first embodiment it is as follows. That is, as shown in FIG. 2, a first connecting part 61a (for example, a first connecting part 61a which is an L-shaped plate-like body) attached to the switch main body 54 of the switch 50 by a fixture. , The second connecting portion 61b (for example, the second connecting portion 61b which is an L-shaped plate-like body) attached to the drive portion 61 by the fixing tool, and the third connecting portion 61c ( For example, the input shaft 51 of the switch 50 and the rotary shaft of the drive unit 61 are connected to each other via the cylindrical third connecting portion 61c which can be fitted to each of the input shaft 51 of the switch 50 and the rotary shaft of the drive unit 61. The drive unit 61 is removably installed in the switchgear 50 by detachably connecting. However, the present invention is not limited to this, and the drive unit 61 may be installed in the switchgear 50 in a non-detachable manner, for example, by welding.

(Structure-Hoisting system-First connector part)
Returning to FIG. 1, the first connector section 62 is a connector for detachably connecting the power supply side wiring 5 directly or indirectly connected to the power supply section 69 that supplies power to the drive section 61. The first connector portion 62 is configured by using, for example, a known connector (for example, a male connector or a female connector), and is provided in the vicinity of the opening 3.

Further, the method of installing the first connector portion 62 is arbitrary, but in the first embodiment, an operator located on the floor surface 9a attaches the first connector portion 62 to the first connector portion 62 and the power supply side wiring 5 ( Specifically, it is installed (arranged) at a position H1 (hereinafter referred to as "workable position H1") where attachment/detachment work with the first power supply side wiring 5a) can be performed. Specifically, as shown in FIG. 1, the first connector portion 62 is accommodated inside the connector accommodating portion 67, and the portion of the skeleton 2 located in the vicinity of the opening 3 is closer to the floor surface 9a. Is also installed (attached) indirectly to the upper part. Here, the “workable position H1” is specifically a position below the storage unit 10 and a position above the floor surface 9a, and is located on the floor surface 9a. This is a position where a person can attach and detach the first connector portion 62 and the power-source-side wiring 5 without using a tool, and for example, a position apart from the floor surface 9a by about 800 mm to 1500 mm or the like. By such installation, the worker can perform the above-mentioned attachment/detachment work while on the ground, and according to the conventional technique (the connector is arranged inside the shutter housing portion and the connector is located above the operation portion outside the shutter housing portion). Compared with the (arranged technology), the worker does not need to perform the attachment/detachment work in the vicinity of the storage section 10, so that the attachment/detachment work can be performed easily and safely. In particular, since the first connector portion 62 is indirectly attached to a portion of the body 2 located near the opening 3 above the floor surface 9a, the workability of the attachment/detachment work is maintained. However, the 1st connector part 62 can be attached stably.

(Structure-Winding system-Second connector part)
The second connector portion 63 is for electrically connecting to the first connector portion 62. The second connector portion 63 is configured by using, for example, a well-known connector (for example, a male connector or a female connector) that is detachable from the first connector portion 62, and as shown in FIG. It is attached to the end of the side wiring 5a on the first connector 62 side.

(Structure-Winding system-Third connector part)
The third connector portion 64 is for electrically connecting to the cord reel 68 (or the power source portion 69). The third connector portion 64 is configured by using, for example, a well-known detachable connector (for example, a male connector or a female connector) and the like of the connector portion of the cord reel 68, and as shown in FIG. It is attached to the end of the power supply side wiring 5b on the power supply section 69 side.

(Structure-Winding system-Upper limit detector)
The upper limit detection unit 65 detects whether the lower end of the opening/closing body 30 has reached a position (hereinafter, referred to as “upper limit position”) flush with the ceiling 9b of the building, and the lower end of the opening/closing body 30 is detected. When it is detected that the upper limit position has been reached, the upper limit detector outputs an upper limit signal indicating that fact. The upper limit detection unit 65 is configured by using, for example, a known detection sensor (as an example, a counter type limit switch or the like), and as shown in FIG. 1, a position near the switch 50 outside the storage unit 10. It is provided in.

(Structure-Hoisting system-Number of times detection unit)
The number-of-times detection unit 66 detects the number of times the drive unit 61 has been used, and outputs a signal indicating that when the detected number of uses exceeds a threshold value (hereinafter referred to as a “limit number signal”). Is. Here, the “number of times the drive unit 61 is used” will be described as the number of times the drive unit 61 is energized via the first connector unit 62, the power supply side wiring 5, and the drive side wiring 4 in the first embodiment. However, not limited to this, for example, the number of times the upper limit signal is output from the upper limit detection unit 65 in a state in which the drive unit 61 is energized via the first connector unit 62, the power supply side wiring 5, and the drive side wiring 4. It may be. The number-of-times detection unit 66 is configured by using, for example, a known detection sensor (as an example, a counter capable of displaying the number of times the drive unit 61 has been used), and as shown in FIG. It is provided in.

(Structure-Hoisting system-Connector housing)
The connector storage portion 67 is a connector storage means for storing at least the first connector portion 62 (in the first embodiment, the first connector portion 62 and the number-of-times detecting portion 66 are stored). The connector storage section 67 is configured using, for example, a known storage case (as an example, an openable steel storage case), and more specifically, as shown in FIG. A partially opened hollow main body 67a, which houses the first connector portion 62 and the number-of-times detecting portion 66, and is openably and closably attached to the main body 67a, and the main body 67a is opened. A lid portion 67b that closes the end and a locking portion 67c that locks the lid portion 67b are provided.

Although the method of installing the connector housing portion 67 is arbitrary, in the first embodiment, the first connector portion 62 and the number-of-times detecting portion 66 are installed at positions where they can be housed. As shown in FIG. 3, the frame 2 is arranged at the workable position H1 and a portion corresponding to the vicinity thereof, and is attached to the frame 2 (or the guide rail 20) by a fixture or the like.

With such a configuration of the connector storage portion 67, the first connector portion 62 can be stored in the connector storage portion 67. Therefore, since it is possible to prevent the first connector portion 62 from being exposed from the outside, it is easy to avoid, for example, inadvertently touching the first connector portion 62 by a third party when the first connector portion 62 is permanently installed. Become.

(Structure-Hoisting system-Upper side control unit)
Returning to FIG. 1, the hoisting side control unit 70 is a unit for controlling the hoisting system 60. As shown in FIG. 1, the hoisting side control unit 70 is provided outside the storage section 10, and is provided with a hoisting side operation section 71, a hoisting side input section (not shown), a hoisting side output section (not shown), A winding-up power supply unit (not shown) and a winding-up control unit (not shown) are provided. Note that the respective parts that constitute the winding-up side control unit 70 are electrically connected to each other via wiring (specifically, other wiring different from the power supply side wiring 5 and the drive side wiring 4) not shown. (That is, the winding-up operation unit 71 is electrically connected to the winding-up control unit via the other wiring).

(Structure-Hoisting system-Upper side control unit-Upper side operation section)
The winding-up operation unit 71 is an operation unit that receives an operation input to the winding system 60. The winding-up operation unit 71 is configured by using, for example, a known operation means (a push button switch or the like, for example), and as shown in FIG. 1, a rotation direction changeover switch 71a, a start switch 71b, and a stop. The switch 71c is provided.

The rotation direction changeover switch 71a is a switch for instructing switching of the rotation direction of the rotation shaft of the drive unit 61, and when the rotation direction changeover switch 71a is operated, it outputs a switching signal indicating the instruction. Here, the reason for providing the rotation direction changeover switch 71a is as follows. That is, the same opening/closing device 50 may be installed left-rightly differently, and the rotation direction for winding up the opening/closing body 30 may be different due to the difference in the installation direction of the opening/closing device 50. It is necessary to switch the rotation direction of the rotary shaft according to the direction. In order to enable such switching, a rotation direction changeover switch 71a is provided.

The activation switch 71b is a switch for instructing the drive unit 61 to wind up the opening/closing body 30, and when the activation switch 71b is operated, it outputs a hoisting signal indicating the instruction.

The stop switch 71c is a switch for instructing the drive unit 61 to stop the winding of the opening/closing body 30, and when the stop switch 71c is operated, it outputs a stop signal indicating the instruction.

In addition, the method of installing the hoisting operation unit 71 is arbitrary, but in the first embodiment, the position H2 (where the operator can operate the hoisting operation unit 71 while standing on the floor 9a). Hereinafter, it is installed in the “operable position H2”), and specifically, it is installed in a detachable manner with respect to the opening/closing body 30, the guide rail 20, or the body 2. Here, the “operable position H2” is specifically a position below the storage unit 10 and above the floor 9a, as shown in FIG. It is a position where an operator located on the floor surface 9a can operate the hoisting side operation unit 71 without using a tool, and for example, a position above the floor surface 9a that is about 800 mm to 1500 mm away. To do. With such an installation, the operator can operate the drive unit 61 via the hoisting operation unit 71 while on the ground, and compared to the case where the hoisting operation unit 71 is installed near the storage unit 10, The operator can easily and safely operate the hoisting operation unit 71. However, the present invention is not limited to this, and, for example, the winding-up operation unit 71 may not be installed on the predetermined installation target, but may be held by the operator when operating the winding-up operation unit 71.

Further, the method of outputting the hoisting signal by the hoisting operation unit 71 is arbitrary, but in the first embodiment, the hoisting signal is output after the start switch 71b is operated, and the operation is not continued thereafter. However, the hoisting signal is continuously output (the hoisting signal is output according to the so-called "self-holding operation"). This eliminates the need for the operator to stick to the winding-up operation portion 71 for operating the start-up switch 71b, so that the operator can wind up the opening/closing body 30 while performing another work. However, without being limited to this, for example, the hoisting signal may be output after the activation switch 71b is operated, and the hoisting signal may be continuously output only while the operation is continuously performed thereafter ( A hoisting signal may be output according to a so-called "push-off operation").

(Structure-Hoisting system-Upper side control unit-Upper side input section)
The winding side input unit is an input unit that receives inputs of a winding signal, a stop signal, a switching signal, an upper limit signal, and a limit frequency signal, and is configured using, for example, a known input terminal.

(Structure-Hoisting system-Upper side control unit-Upper side output section)
The winding-up output unit is an output unit that outputs the signal output from the winding-up control unit to the drive unit 61, and is configured using, for example, a known output terminal.

(Structure-Hoisting system-Upper side control unit-Upper side power supply unit)
The winding-side power supply unit supplies the power supplied from the power supply unit 69 via the second power-source-side wiring 5b and the wiring 68a of the cord reel 68 to each unit of the winding-side control unit 70 and also to the drive unit 61. It is a power supply means for.

(Structure-Hoisting system-Upside control unit-Upside control unit)
The winding-up control unit is a control unit that controls each unit of the winding-up control unit 70 and controls the drive unit 61 based on the presence or absence of the winding signal input by the operating unit. Specifically, the control unit includes a CPU, various programs that are interpreted and executed on the CPU (including a basic control program such as an OS and an application program that is started on the OS and realizes a specific function), programs, and the like. This is a computer including an internal memory such as a RAM for storing various data (the same applies to the configuration of other control units described later). The details of the processing executed by the winding control section will be described later.

(Configuration-Hoisting system-Other configurations)
Although the specific configuration of the hoisting system 60 is arbitrary, in the first embodiment, the hoisting side control unit and the first connector unit 62 are connected to each other via the first power supply side wiring 5a. At the same time, the winding-side control section and the power supply section 69 are connected to each other via the second power-side wiring 5b, so that the power-supply side wiring 5, the winding-side operation section 71, and the winding-side control section can be transported. It is configured. Specifically, as described above, the power supply side wiring 5 is detachably connected to the first connector portion 62 via the second connector portion 63. As for the winding-up operation section 71 and the winding-up control section, a winding-up control unit 70 including them is detachably installed on the opening/closing body 30, the guide rail 20, or the body 2. As a result, the power supply side wiring 5, the winding-up operation unit 71, and the winding-up control unit can be collectively conveyed. Therefore, for example, when a plurality of opening/closing devices 1 each including the opening/closing body 30, the opening/closing device 50, the drive unit 61, the first connector unit 62, and the drive side wiring 4 are installed in a building, the power supply side wiring 5, the winding side It is possible to wind the opening/closing body 30 of each opening/closing device 1 by using only one set including the operation unit 71 and the hoisting side control unit, which reduces the installation cost of the hoisting system 60. It becomes easier to reduce the amount.

With such a hoisting system 60, the hoisting system 60 of the hoisting system 60 can be compared with the prior art (a technique of arranging the connector inside the shutter housing portion and arranging the connector outside the shutter housing portion above the operating portion). It becomes possible to improve usability.

(Control processing)
Next, a control process executed by the winding system 60 configured as above will be described. In the following description, the step is abbreviated as “S” in the description of the control process shown in FIG. The control process is a process for controlling the winding system 60. Although the timing of executing this control process is arbitrary, in the first embodiment, after the power of the drive unit 61, the upper limit detection unit 65, the number of times detection unit 66, and the winding-side control unit 70 of the hoisting system 60 is turned on. It will be described as being activated.

Further, the premise of this control processing is as follows in the first embodiment. That is, the control process is performed by performing the first operation of the operation unit for the manual closing device so that the state of the opening 3 is changed from the fully open state to the fully closed state in the operation confirmation work of the switchgear 1. It is assumed that the operation is performed when the state of the opening 3 is returned to the fully open state after the self-closing movement of the opening/closing body 50 by the device is performed (that is, the hoisting side operation unit 71 of the hoisting system 60 is operated. Therefore, the opening/closing body 50 is wound using the drive unit 61). From this, the state of the opening 3 is assumed to be a fully closed state. Further, the rotation direction of the drive unit 61 is switched in advance via the rotation direction changeover switch 71a of the winding-up operation unit 71 so that the opening/closing body 30 can be wound up. ..

When the control process is started, as shown in FIG. 5, in SA1, the hoisting side control unit of the hoisting side control unit 70 determines whether or not the input of the hoisting signal is accepted by the hoisting side input unit. Then, the winding-up control unit of the winding-up control unit 70 waits until it is determined that the input of the winding signal is received (SA1, No), and when it is determined that the input of the winding signal is received (SA1). , Yes), the process proceeds to SA2.

In SA2, the hoisting side control unit of the hoisting side control unit 70 determines whether or not the input of the stop signal, the upper limit signal, or the limit number of times signal has been accepted by the hoisting side input unit. Then, when it is determined that the input of the stop signal, the upper limit signal, or the limit number of times signal is not accepted (SA2, No), the winding side control unit of the winding side control unit 70 proceeds to SA3 and stops the stop signal. If it is determined that the input of the upper limit signal or the limit number of times signal is accepted (SA2, Yes), the process proceeds to SA5.

At SA3, the hoisting side control unit of the hoisting side control unit 70 determines whether or not the acceptance of the hoisting signal input by SA1 is continuing. Then, when it is determined that the input of the hoisting signal by SA1 continues to be received (SA3, Yes), the hoisting side control unit of the hoisting side control unit 70 proceeds to SA4, and the hoisting signal by SA1. If it is not determined that the acceptance of the input is continued (No in SA3), the process proceeds to SA5.

In SA4, the winding-up control unit of the winding-up control unit 70 drives the drive unit 61 so as to wind up the opening/closing body 30. After that, the winding-up control unit of the winding-up control unit 70 shifts to SA2 until the input of the stop signal, the upper limit signal, or the limit number of signals is accepted at SA2, or the input of the winding signal at SA3. The processes of SA2 to SA4 are repeated until the acceptance is not continued (that is, the drive of the drive unit 61 is continuously executed). Although the driving method of the driving unit 61 is arbitrary, in the first embodiment, the driving of the driving unit 61 is continued from the time SA4 is executed until the time SA5 described later is executed.

In SA5, the winding-up control unit of the winding-up control unit 70 stops the driving of the drive unit 61, then shifts to SA1, and repeats the processing from SA1 to SA6. If the process of SA4 is not performed before the process of SA5 (that is, the drive unit 61 is stopped), the process may be shifted to SA1 without performing the process of SA5.

By the control processing as described above, the drive unit 61 can be controlled based on whether or not the hoisting signal is input by the hoist input unit, and the opening/closing body 30 can be hoisted at a timing according to the situation of the operator. You can

(effect)
As described above, according to the first embodiment, the first connector portion 62 provided on the outside of the storage portion 10 and attached to the drive side wiring 4 directly or indirectly connected to the drive portion 61 , A first connector portion 62 for detachably connecting the power source side wiring 5 directly or indirectly connected to a power source portion 69 that supplies power to the drive portion 61, and the first connector portion 62 is Since the worker located on the floor surface 9a of the first connector portion 62 and the power supply side wiring 5 is arranged at a position where the worker can perform the attaching/detaching work, the worker can perform the attaching/detaching work while being on the ground. Compared with the conventional technology (technology in which the connector is arranged inside the shutter housing portion and the connector is arranged outside the shutter housing portion and above the operating portion), the worker performs the above-described attachment/detachment work near the housing portion 10. Since it is not necessary to carry out, it is possible to easily and safely carry out the attachment/detachment work.

Further, since the first connector portion 62 is directly or indirectly attached to a portion of the building body 2 located in the vicinity of the opening 3 above the floor surface 9a, the work of the attachment/detachment work is performed. The 1st connector part 62 can be attached stably, maintaining a sex.

Further, since the connector accommodating portion 67 for accommodating the first connector portion 62 is provided, the connector accommodating portion 67 can accommodate the first connector portion 62. Therefore, since it is possible to prevent the first connector portion 62 from being exposed from the outside, it is easy to avoid accidentally touching the connector by a third party when the first connector portion 62 is permanently installed, for example.

Further, the winding-up operation unit 71 and the winding-up control unit electrically connected to the winding-up operation unit 71 are provided, and the winding-up control unit and the first connector unit 62 are connected via the first power supply side wiring 5a. Are connected to each other, and the winding-side control section and the power supply section 69 are connected to each other via the second power-side wiring 5b, so that the power-side wiring 5, the winding-side operation section 71, and the winding-side control section are connected to each other. Since it is possible to carry, the power supply side wiring 5, the winding-side operation unit 71, and the winding-side control unit can be collectively carried. Therefore, for example, when a plurality of opening/closing devices 1 each including the opening/closing body 30, the opening/closing device 50, the drive unit 61, the first connector unit 62, and the drive side wiring 4 are installed in a building, the power supply side wiring 5, the winding side It is possible to wind the opening/closing body 30 of each opening/closing device 1 by using only one set including the operation unit 71 and the hoisting side control unit, which reduces the installation cost of the hoisting system 60. It becomes easier to reduce the amount.

Further, since the power supply unit 69 is a commercial AC power supply of 100V, it is relatively easy to secure electric power as compared with other power supply means, and thus the usability of the hoisting system 60 is easily improved.

[Embodiment 2]
Next, the winding system according to the second embodiment will be described. The second embodiment is a manual shutter device, and is a form including a winding-side control unit connected to drive-side wiring. However, the configuration and the processing according to the second embodiment are the same as the configuration and the processing according to the first embodiment unless otherwise described, and the same configuration and processing are the same as those in the first embodiment. The same name or reference numeral as that used is used as necessary, and the description thereof is omitted.

(Constitution)
First, the configuration of the switchgear according to the second embodiment will be described. The opening/closing device 100 according to the second embodiment has substantially the same configuration as the opening/closing device 1 according to the first embodiment. However, the details of the configuration of the hoisting system 60 have been devised as follows.

(Structure-Hoisting system)
Next, details of the configuration of the winding system 60 will be described. As shown in FIG. 6, the hoisting system 60 includes a drive unit 61, a first connector unit 62, a second connector unit 63, a third connector unit 64, an upper limit detection unit 65, a number-of-times detection unit 66, an upper winding operation unit 71, A connector housing portion 67 and a winding-side control unit 70 are provided. Of these, as shown in FIG. 6, the hoisting side control unit 70 is provided outside the storage section 10, and includes a hoisting side input section, a hoisting side output section, a hoisting side power supply section, and a hoisting side control section. It is provided (all are not shown).

Further, the method of connecting the respective parts constituting the winding system 60 is arbitrary, but in the second embodiment it is as follows. That is, as shown in FIG. 6, the first connector portion 62 is electrically connected to the drive portion 61 and the winding-side control unit 70 via the drive-side wiring 4. Specifically, the drive-side wiring 4 is the first drive-side wiring 4 a located on the side of the first connector portion 62 (specifically, the first drive-side wiring 4 a extending from the winding-up control unit 70 or the first connector portion 62 ). Drive side wiring 4a) and second drive side wiring 4b located on the side of the drive section 61 (specifically, second power source side wiring 5b extending from the drive section 61 or the winding-side control unit 70). Therefore, the first connector portion 62 and the winding-up control unit 70 are connected to each other via the first driving-side wiring 4a, and the winding-up control unit 70 and the driving portion 61 are connected to each other via the second driving-side wiring 4b. Are connected to each other. Further, the first connector portion 62 is electrically connected to the power source portion 69 via the power source side wiring 5, the second connector portion 63, the third connector portion 64, and the cord reel 68. The upper limit detection unit 65 is electrically connected to the drive unit 61 via the first detection-side wiring 6, and the winding-up operation unit 71 and the number-of-times detection unit 66 are connected to each other via the second detection-side wiring. It is electrically connected to the 1 connector portion 62.

By the connection as described above, the winding-up control unit 70 and each of the drive unit 61, the upper limit detection unit 65, the number-of-times detection unit 66, and the winding-up operation unit 71 can directly or indirectly communicate with each other. It will be possible. Further, it becomes possible to directly or indirectly supply the electric power from the power supply unit 69 to the winding-up side control unit 70, the drive unit 61, the upper limit detecting unit 65, the number-of-times detecting unit 66, and the winding-up operation unit 71. .. In the second embodiment, the first driving side wiring 4a, the second driving side wiring 4b, the first detection side wiring 6, and the second detection side wiring function as a power line as well as a signal line. I will explain as things. Further, the power supply side wiring 5 will be described as one that functions only as a power supply line.

(Structure-Hoisting system-Upper side operation part)
As shown in FIG. 6, the winding-side operation portion 71 is provided outside the storage portion 10 and includes a start switch 71b.

Further, the method of outputting the hoisting signal by the hoisting side operation unit 71 is arbitrary, but in the second embodiment, the hoisting signal is output according to the above-mentioned push-off operation. Accordingly, without providing the stop switch 71c on the winding-up operation portion 71, the winding and closing of the opening/closing body 30 can be executed and interrupted depending on how the operator operates the start switch 71b. The configuration can be simplified. However, the present invention is not limited to this, and for example, a hoisting signal may be output according to the above-described self-holding operation.

(Configuration-Hoisting system-Other configurations)
Although the specific configuration of the hoisting system 60 is arbitrary, in the second embodiment, the hoisting side control unit and the first connector unit 62 are connected to each other via the first drive side wiring 4a, and By connecting the winding-up side control section and the driving section 61 to each other via the second drive-side wiring 4b, the winding-up side operation section 71 and the winding-up side control section can be installed in the frame 2 or the storage section 10. It is configured. Specifically, as shown in FIGS. 6 and 7, the winding-side operation section 71 is installed at the operable position H2 inside the connector storage section 67. In this case, the connector accommodating portion 67 has a shape and a size capable of accommodating the first connector portion 62, the number-of-times detecting portion 66, and the winding-side operation portion 71. As for the winding-up control section, a winding-up control unit 70 including this is stored inside the connector storage section 67. Accordingly, the drive-side wiring 4, the winding-side operation unit 71, and the winding-side control unit can be collectively installed in the skeleton 2 or the storage unit 10. Therefore, it is not necessary to convey the winding-up side control unit and the winding-up side operation unit 71 when performing the attaching/detaching work, and compared with the case where the winding-side control unit and the winding-up side operation unit 71 are connected using the power supply side wiring 5. As a result, the efficiency of the attachment/detachment work can be facilitated.

(Control processing)
Next, a control process executed by the winding system 60 configured as above will be described. The control process according to the second embodiment is almost the same as the control process according to the first embodiment, and thus the description of the process is omitted.

(effect)
As described above, according to the second embodiment, the winding-up operation portion 71, which is provided outside the storage portion 10 and is electrically connected to the first connector portion 62, is provided outside or inside the storage portion 10. And a winding-up control unit that connects the winding-up control unit and the first connector unit 62 to each other via the first drive-side wiring 4a, and also a winding-up control unit via the second driving-side wiring 4b. Since the winding-up operation unit 71 and the winding-up control unit can be installed in the skeleton 2 of the building or the storage unit 10 by mutually connecting the driving unit 61 and the driving unit 61, the drive-side wiring 4, the winding-up operation unit 71, And the winding-up side control part can be installed together in the skeleton 2 or the storage part 10. Therefore, it is not necessary to convey the winding-up side control unit and the winding-up side operation unit 71 when performing the attaching/detaching work, and compared with the case where the winding-side control unit and the winding-up side operation unit 71 are connected using the power supply side wiring 5. As a result, the efficiency of the attachment/detachment work is facilitated.

[Embodiment 3]
Next, a winding system according to the third embodiment will be described. The third embodiment is an electric shutter device, and is a form including a winding-side control unit connected to drive-side wiring. However, the configuration and the processing according to the third embodiment are the same as the configuration and the processing according to the second embodiment unless otherwise specified, and the same configuration and processing are the same as those in the second embodiment. The same name or reference numeral as that used is used as necessary, and the description thereof is omitted.

(Constitution)
First, the configuration of the switchgear according to the third embodiment will be described. As shown in FIG. 8, the opening/closing device 200 according to the third embodiment schematically includes a storage section 10, a guide rail 20, an opening/closing body 30, a winding shaft 40, a drive side bearing section 41, a driven side bearing section, An opening/closing machine 50, an automatic closing device, a manual closing device 210, an upper/lower limit detecting part 81, an opening/closing side operating part 82, an interlocking repeater (not shown), an opening/closing side control unit 90, and a winding system 60 are provided.

(Structure-Switch)
The opening/closing machine 50 electrically closes or opens the opening/closing body 30 by rotationally driving the winding shaft 40. The switch 50 is configured by using, for example, a known electric switch, and as shown in FIG. 8, an input shaft 51, an output shaft 52, a switch side sprocket 53, a switch main body 54, and a manual operation. The switchgear main body 54 includes a speed reduction unit, a speed control unit, a brake unit, and an open/close side drive unit (all of which are not shown). Of these, the open/close side drive unit is for electrically rotating the output shaft 52, and is configured using, for example, a known drive unit (a motor or the like, for example).

(Structure-Automatic closing device)
The specific operation of the automatic closing device is arbitrary, but in the third embodiment, it is as follows. That is, first, when the interlocking repeater receives a fire signal from the disaster prevention panel and a control signal is received from the interlocking repeater via a wire (not shown), the release lever of the switch 50 is released based on the control signal. The opening/closing body 30 is closed and moved by its own weight by releasing the brake part of the opening/closing machine 50 by operating the opening/closing body 30. After that, when the interlocking repeater receives the recovery signal from the disaster prevention panel to receive the control signal from the interlocking repeater through the wiring, the state before the release lever of the switch 50 is operated to be released based on the control signal. Then, the brake part of the switch 50 is actuated.

(Structure-Manual closing device)
As shown in FIG. 8, the manual closing device 210 is provided outside the storage portion 10 in the vicinity of the opening portion 3, and specifically, contacts the skeleton 2 or is stored in the guide rail 20. Is fixed to the skeleton 2 or the guide rail 20, and is electrically connected to the interlocking repeater via the wiring 201. Further, the manual closing device 210 is configured by using, for example, a known operating means (a push button switch or the like, for example), and specifically, the self-weight for closing and moving the opening/closing body 30 by its own weight. After the input of the fire signal or the self-weight closing signal is received by the emergency button that receives the operation input of the closing control and the interlocking repeater described later, the switchgear 200 is restored to the state before the input of the fire signal is received. A recovery button that accepts control operation input is provided (both not shown).

The specific operation of the manual closing device 210 is arbitrary, but in the third embodiment, it is as follows. That is, first, when the user presses the emergency button, the self-weight closing control signal is output to the automatic closing device via the interlocking relay. Accordingly, the opening/closing body 30 can be closed and moved by its own weight by performing the release operation of the brake part of the opening/closing device 50 by the above-described automatic closing device. After that, when the user presses the recovery button, the recovery control signal is output to the automatic closing device via the interlocking repeater. As a result, the above-described automatic closing device performs an operation of returning to the state before the release operation of the brake portion of the switch 50. In the third embodiment, the manual closing device 210 is described as a device that communicates with the interlocking repeater in a wired manner, but is not limited to this, and may be a device that communicates wirelessly with the interlocking repeater, for example. Both the wired and wireless manual closing devices 210 may be installed (the same applies to the opening/closing side operation unit 82).

(Structure-upper/lower limit detector)
The upper/lower limit detection unit 81 detects whether the lower end of the opening/closing body 30 has reached the upper limit position, and outputs an upper limit signal when it is detected that the lower end of the opening/closing body 30 has reached the upper limit position. At the same time, the lower end of the opening/closing body 30 is set at a position set near the floor surface 9a of the building (for example, a position set a predetermined distance (several cm) above the floor surface 9a. The upper and lower limit detecting means outputs a lower limit signal indicating that the lower limit of the opening/closing body 30 has reached the lower limit position. The upper/lower limit detection unit 81 is configured by using a known detection sensor such as a counter type limit switch, and is installed in the vicinity of the switchgear 50 as shown in FIG. Are connected to each other by a fixture or the like. In addition, in the third embodiment, the upper and lower limit detection unit 81 is electrically connected to the drive unit 61 via the first detection side wiring 6.

(Structure-Opening/closing side operation part)
The opening/closing side operation unit 82 is an opening/closing side operation unit that receives an operation input related to the closing movement or the opening movement of the opening/closing body 30, and is provided near the opening 3 outside the storage unit 10 as illustrated in FIG. 8. Specifically, it is arranged so as to come into contact with the skeleton 2 or be housed in the guide rail 20, and is fixed to the skeleton 2 or the guide rail 20. Further, the opening/closing-side operation unit 82 is configured by using, for example, a known shutter device operating unit (as an example, a push button switch or the like). Specifically, the opening/closing body 30 is opened electrically. It is provided with an opening button for moving, a closing button for closing moving electrically, and a stop button for stopping the closing movement or opening movement by electric (all are not shown). When the open button, the close button, or the stop button is pressed by the user, an operation signal (that is, an open signal, a close signal, a stop signal) corresponding to the pressed button is output to the interlocking repeater and the opening/closing side control unit. By outputting to the opening/closing body 50 via 90, the opening/closing body 30 can be electrically closed or opened by the opening/closing machine 50, or the closing movement or opening movement of the opening/closing body 30 can be electrically stopped.

(Structure-Interlocking repeater)
The interlocking repeater interlocks each part of the switchgear 200. This interlocking repeater is configured using, for example, a known interlocking repeater for a switchgear (as an example, an interlocking repeater having a power source unit such as a battery), and includes an opening/closing device 50, an automatic closing device, and a manual closing device. 210, the opening/closing-side operation unit 82, and the opening/closing-side control unit 90 are electrically connected to each other via wiring (not shown). In the third embodiment, during a power failure of the building, power can be supplied from the interlocking repeater to the automatic closing device and the manual closing device 210, so that the opening/closing body 30 can be closed and moved by its own weight. I have to.

(Structure-Opening/closing side control unit)
The opening/closing side control unit 90 is a unit for controlling the opening/closing of the opening/closing body 30 by the opening/closing machine 50. As shown in FIG. 8, the opening/closing-side control unit 90 is provided outside the storage unit 10, and includes the switch 50, the upper/lower limit detecting unit 81, the opening/closing-side operation unit 82, and the wiring 7 (hereinafter, referred to as “first It is electrically connected via an open/close side wire 7 ”. Some of which are not shown.), and an open/close side input section, an open/close side output section, an open/close side power supply section, an open/close side control section, and an open/close side memory Parts (both not shown).

(Structure-Open/close control unit-Open/close input, open/close output, open/close power supply)
The open/close side input unit is an input unit that receives an input of an operation signal, an upper limit signal, or a lower limit signal, and is configured by using, for example, a known input terminal. The open/close side output unit is an output unit that outputs a signal to the switch 50, and is configured using, for example, a known output terminal. The opening/closing-side power supply unit supplies electric power supplied from a commercial power source or a battery (for example, a battery) not shown to each unit of the opening/closing-side control unit 90, and also to the upper/lower limit detection unit 81 and the opening/closing-side operation unit 82. To supply.

(Structure-Open/close side control unit-Open/close side control unit, open/close side storage unit)
The open/close side control unit is a first control unit that controls each unit of the open/close side control unit 90. In the third embodiment, when the opening/closing body 30 is being closed or opened by the control of the opening/closing control unit based on the input of the operation signal, the opening/closing control unit indicates that fact. A signal (hereinafter, referred to as “opening/closing control signal”) is output to the winding-up control unit 70 via the opening/closing-side output unit. The opening/closing side storage unit stores a program and various data necessary for the operation of the opening/closing side control unit 90 (for example, control position information, closing direction side distance information described below, opening direction side distance information described below, etc.). In this case, a known rewritable recording medium is used, and a non-volatile recording medium such as a flash memory can be used.

(Structure-Hoisting system)
As shown in FIG. 8, the hoisting system 60 includes a drive unit 61, a first connector unit 62, a second connector unit 63, a third connector unit 64, a number-of-times detecting unit 66, a winding-up operation unit 71, a connector storage unit 67, And a winding-up control unit 70. Of these, as shown in FIG. 8, the first connector portion 62 includes a power source portion 69 (specifically, a battery, a generator) via the power source side wiring 5, the second connector portion 63, and the third connector portion 64. Etc.) and is electrically connected. As shown in FIG. 8, the hoisting side control unit 70 is provided outside the storage section 10 and via the opening/closing side control unit 90 and the wiring 8 (hereinafter, referred to as “second opening/closing side wiring 8”). And a winding-up input section, a winding-up output section, a winding-up power supply section, and a winding-up control section. The "winding side control unit" described above corresponds to the "control unit" and the "second control unit" in the claims. The details of the processing executed by the winding control section will be described later.

(Control processing)
Next, a control process executed by the winding system 60 configured as above will be described. Although the timing of executing this control process is arbitrary, in the third embodiment, the switch 50, the upper/lower limit detection unit 81, the opening/closing side operation unit 82, the opening/closing side control unit 90, and the drive unit 61 of the hoisting system 60, The description will be given assuming that the number of times detecting unit 66 and the hoisting side control unit 70 are activated after being turned on. Further, regarding the premise of this control processing, in the third embodiment, in the fully open state, the interlocking repeater receives a fire signal from the disaster prevention panel after a power outage occurs in the building (or from the open/close side operation unit 82 by its own weight). This is executed when the opening/closing body 30 is closed and moved by its own weight by receiving the closing control signal, and then the state of the opening 3 is returned to the fully opened state (that is, the winding-up operation portion 71 of the winding system 60). It is assumed that the opening/closing body 50 is rolled up using the drive unit 61 by performing the operation (1). However, the present invention is not limited to this, and may be executed when returning the state of the opening 3 to the fully open state, for example, when a power failure occurs in the building in the fully closed state.

When the control process is activated, as shown in FIG. 9, in SB1, the hoisting side control unit of the hoisting side control unit 70 determines whether or not the input of the opening/closing control signal is accepted by the hoisting side input unit. Then, the winding-up control unit of the winding-up control unit 70 waits until it is determined that the input of the opening/closing control signal has not been received (SB1, Yes), and determines that the input of the opening/closing control signal has not been received. If (SB1, No), the process proceeds to SB2. Due to such processing, the processing of SB2 to SB7, which will be described later, cannot be executed while the opening/closing side control section of the opening/closing side control unit 90 is controlling the opening/closing side 50. Since the control of 50 and the control of the drive unit 61 by the hoisting side control unit are performed at the same time, it is possible to avoid a failure of the switch 50 or the drive unit 61.

At SB2, the hoisting side control unit of the hoisting side control unit 70 determines whether or not the input of the hoisting signal is accepted by the hoisting side input unit. Then, when it is not determined that the input of the hoisting signal is accepted (SB2, No), the hoisting side control unit of the hoist upper control unit 70 proceeds to SB1 and determines that the input of the hoist signal is accepted. If it is (SB2, Yes), the process proceeds to SB3.

In SB3, the winding-up control unit of the winding-up control unit 70 determines whether the input of the stop signal, the upper limit signal, or the limit number of times signal has been accepted by the winding-up input unit. Then, when it is determined that the stop signal, the upper limit signal, or the limit number of times signal is not received (SB3, No), the wind-up side control unit of the winding side control unit 70 proceeds to SB4 and stops the stop signal. If it is determined that the input of the upper limit signal or the limit number of times signal is accepted (SB3, Yes), the process proceeds to SB7.

At SB4, the hoisting control unit of the hoisting control unit 70 determines whether or not the input of the hoisting signal by SB2 continues to be accepted. Then, when it is determined that the input of the hoisting signal by SB2 continues to be received (SB4, Yes), the hoisting side control unit of the hoisting side control unit 70 proceeds to SB5 and the hoisting signal by SB2. If it is not determined that the acceptance of the input is continued (SB4, No), the process proceeds to SB7.

At SB5, the hoisting side control unit of the hoisting side control unit 70 outputs a signal (hereinafter, referred to as a "stop signal") for instructing to stop the control of the switch 50 by the opening/closing side control unit via the hoisting side output unit. Output to the open/close side control unit 90. The method of outputting the stop signal is arbitrary, but in the third embodiment, it is continuously or intermittently output from the time when the process of SB5 is executed until the time when SB7 described later is executed. As a result, when the hoisting side control unit receives the input of the hoisting signal, the stop signal can be output to the opening/closing side control unit. Control can be stopped. Therefore, as compared with the case where the stop signal is not output, the control of the opening/closing device 50 by the opening/closing side control unit and the control of the driving unit 61 by the hoisting side control unit are performed simultaneously, so that the opening/closing device 50 or the driving unit 61 is It is possible to avoid failure.

At SB6, the winding-up control unit of the winding-up control unit 70 drives the drive unit 61 to wind up the opening/closing body 30. After that, the winding-up control unit of the winding-up control unit 70 shifts to SB3 until the input of the stop signal, the upper limit signal, or the limit number of signals is received at SB3, or the winding signal is input at SB4. The processes of SB3 to SB6 are repeated until the acceptance is not continued (that is, the drive of the drive unit 61 is continuously executed).

In SB7, the hoisting side control unit of the hoisting side control unit 70 stops driving of the drive unit 61 and stops outputting the stop signal. After that, the process proceeds to SB1 and the processes of SB1 to SB7 are repeated. If SB5 and SB6 are not processed before SB7, SB1 may be skipped without performing SB7.

By the control processing as described above, the drive section 61 can be controlled by the opening/closing side control section according to the control status of the opening/closing machine 50, so that the usability of the hoisting system 60 can be improved.

(effect)
As described above, according to the third embodiment, the opening/closing switch 50 is an electric opening/closing switch controlled by the opening/closing-side control unit, and the winding-up operation unit 71 that receives the input of the winding signal and the winding-up operation unit. A winding-up side control unit that controls the drive unit 61 based on the presence or absence of input of the winding-up signal received at 71, and the winding-up side control unit receives the input of the winding-up signal by the winding-up operation unit 71. If the stop signal is output, the stop signal is output to the opening/closing control unit. Therefore, compared with the case where the stop signal is not output, the opening/closing control unit controls the switch 50 and the opening/closing side control unit drives. Since the control of the unit 61 is performed at the same time, it is possible to avoid the failure of the switch 50 or the drive unit 61.

[III] Modifications to Embodiments The embodiments of the present invention have been described above, but the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. , And can be arbitrarily modified and improved. Hereinafter, such a modified example will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the contents described above, and the present invention solves problems not described above or effects not described above. In some cases, only some of the problems described may be solved, or only some of the effects described may be achieved.

(About distribution and integration)
Further, each of the above-mentioned electrical components is functionally conceptual, and does not necessarily have to be physically configured as illustrated. That is, the specific form of distribution and integration of each unit is not limited to that shown in the figure, and all or a part of them may be functionally or physically distributed or integrated in arbitrary units according to various loads and usage conditions. Can be configured. Further, the “device” in the present application is not limited to a device configured by a single device, and includes a device configured by a plurality of devices.

(About shape, numerical value, structure, time series)
Regarding the components illustrated in the embodiments and drawings, the shapes, numerical values, or the structure or the time-series relationship of a plurality of components may be arbitrarily modified and improved within the scope of the technical idea of the present invention. You can

(Applies to the winding system)
Although the winding system 60 is the electric shutter device and is applied to the opening/closing device including the winding-side control unit connected to the drive-side wiring 4 in the third embodiment, the winding system 60 is not limited to this. For example, the shutter device may be an electric shutter device, and may be applied to an opening/closing device including a winding-side control unit connected to the power supply side wiring 5. The control process in this case is performed similarly to the control process according to the third embodiment.

(About switchgear)
In the above-described first to third embodiments, the switch 50, the drive unit 61, and the hoisting side control unit 70 are described as being provided outside the storage unit 10. However, the present invention is not limited to this, and for example, the switch 50, At least a part of the drive unit 61 or the winding control unit 70 may be provided inside the storage unit 10.

(About winding system)
Although the winding system 60 has been described as including the number-of-times detecting unit 66 and the connector storage unit 67 in the first to third embodiments, the present invention is not limited to this. For example, at least the number-of-times detecting unit 66 or the connector storage unit 67. Either one may be omitted. Here, when the connector storage portion 67 is omitted, the first connector portion 62 may be directly attached to the skeleton 2, or indirectly via the guide rail 20 to the skeleton 2. It may be attached.

Further, in the above-described first to third embodiments, it has been described that the power supply side wiring 5 is indirectly connected to the power supply unit 69 via the cord reel 68, but the present invention is not limited to this. For example, the cord reel 68 may be omitted and the power supply unit 69 may be directly connected.

Further, in the first and second embodiments described above, the power supply unit 69 that supplies electric power to the drive unit 61 has been described as a 100V commercial AC power supply, but the present invention is not limited to this, and, for example, other than a 100V commercial AC power supply. Other power supply means (200 V commercial AC power supply, battery, generator, etc.) may be used.

(About connector compartment)
In the first to third embodiments described above, the connector storage portion 67 has been described as including the locking portion 67c, but the locking portion 67c may be omitted.

In addition, in the third embodiment, it is described that the connector housing portion 67 houses the first connector portion 62, the number-of-times detecting portion 66, and the winding-side operation portion 71, but the present invention is not limited to this. Thus, the opening/closing side operation unit 82 may be housed.

(About the winding operation part)
In the above-described first embodiment, it has been described that the winding-up operation unit 71 is electrically connected to the winding-up control unit via another wiring different from the power supply side wiring 5 and the driving side wiring 4. Not limited to this, for example, it may be electrically connected to the first power source side wiring 5a or the second power source side wiring 5b.

In addition, in the above-described second and third embodiments, the winding-side operation portion 71 has the first connector portion 62 via the second detection side wiring (that is, another wiring different from the power supply side wiring 5 and the driving side wiring 4). However, the present invention is not limited to this, and may be electrically connected to, for example, the first drive side wiring 4a, the second drive side wiring 4b, or the power supply side wiring 5.

Further, in the above-described third embodiment, the winding-up operation portion 71 is described as being stored in the connector storage portion 67, but the present invention is not limited to this. May be.

(Appendix)
The hoisting system according to appendix 1 is a hoisting system for hoisting an opening/closing body for opening and closing an opening of a building through a switch, which is drive means connected to a rotating shaft of the switch. A drive means for electrically driving the opening/closing device, and a connector provided outside the housing means for housing the opening/closing body and attached to a drive-side wiring that is directly or indirectly connected to the driving means. And a connector for detachably connecting a power supply side wiring directly or indirectly connected to a power supply means for supplying electric power to the drive means, the connector being a floor surface of the building. Was placed at a position where a worker located in can connect and disconnect the connector and the power supply side wiring.

The winding system according to appendix 2 is the winding system according to appendix 1, in which the connector is directly or directly attached to a portion of the skeleton of the building located in the vicinity of the opening above the floor surface. Attached indirectly.

The winding system according to attachment 3 is the winding system according to attachment 1 or 2, further comprising connector housing means for housing the connector.

The winding system according to supplementary note 4 is the winding system according to any one of supplementary notes 1 to 3, wherein the operating means receives an input of a winding signal that instructs the winding of the opening/closing body by driving the driving means, and the operation. A control means electrically connected to the control means, the control means controlling the drive means based on whether or not the hoisting signal is input by the operating means. A first power source side wiring and a second power source side wiring located on the power source means side, and the control means and the connector are mutually connected via the first power source side wiring. By connecting the control means and the power supply means to each other via the second power supply side wiring, the power supply side wiring, the operating means, and the control means can be conveyed.

The winding system according to appendix 5 is the winding system according to any one of appendices 1 to 3, which is an operating means provided outside the housing means and electrically connected to the connector, An operating means for receiving an input of a hoisting signal for instructing the hoisting of the opening/closing body by driving the means, and the external means provided inside or outside the housing means, and based on the presence or absence of the input of the hoisting signal by the operating means. Control means for controlling drive means, the drive side wiring includes a first drive side wiring located on the connector side, and a second drive side wiring located on the drive means side, By connecting the control means and the connector to each other via the first drive side wiring, and connecting the control means and the drive means to each other via the second drive side wiring, the operation means and The control means can be installed in the body of the building or the storage means.

The winding system according to attachment 6 is the winding system according to any one of attachments 1 to 3, wherein the opening/closing device is an electric opening/closing device controlled by the first control means, and the opening/closing body is driven by the driving means. An operating means for receiving an input of a hoisting signal for instructing hoisting, and a second control means for controlling the driving means based on the presence or absence of the input of the hoisting signal received by the operating means, The second control means, when the input of the hoisting signal by the operation means is accepted, sends the stop signal for instructing to stop the control of the switchgear by the first control means to the first control signal. Output to the control means.

The winding system according to attachment 7 is the winding system according to any one of attachments 1 to 6, wherein the power supply means is a commercial AC power supply of 100V.

(Effect of additional notes)
According to the winding system described in appendix 1, the connector is attached to the drive side wiring that is provided outside the storage means and that is directly or indirectly connected to the drive means, and supplies electric power to the drive means. A connector for removably connecting the power supply side wiring directly or indirectly connected to the power supply means, and the worker located on the floor of the building attaches and detaches the connector and the power supply side wiring. Since the work is arranged at a position where it can be carried out, the worker can perform the above-mentioned attachment/detachment work while on the ground, and the conventional technique (the connector is arranged inside the shutter housing portion and the connector is operated outside the shutter housing portion). As compared with the technique of arranging above the section), the worker does not need to perform the attaching/detaching work in the vicinity of the storage means, so that the attaching/detaching work can be performed easily and safely.

According to the hoisting system described in appendix 2, the connector is directly or indirectly attached to a portion of the building body located in the vicinity of the opening above the floor surface. It is possible to stably attach the connector while maintaining the workability of.

According to the winding system described in appendix 3, since the connector housing means for housing the connector is provided, the connector can be housed in the connector housing means. Therefore, it is possible to prevent the connector from being exposed from the outside, so that it is easy to avoid accidentally touching the connector by a third party when the connector is permanently installed, for example.

According to the winding system described in appendix 4, the operating means and the control means electrically connected to the operating means are provided, and the control means and the connector are mutually connected via the first power source side wiring. By connecting the control means and the power supply means to each other via the second power supply side wiring, the power supply side wiring, the operating means, and the control means can be carried. Therefore, the power supply side wiring, the operating means, and the control means Can be collectively transported. Therefore, for example, in a case where a plurality of opening/closing devices, an opening/closing device, a driving means, a connector, and a switching device including a driving side wiring are installed in a building, one set including a power side wiring, an operating means, and a control means is provided. By simply preparing this, the opening/closing body of each opening/closing device can be wound using this set, and the installation cost of the winding system can be easily reduced.

According to the hoisting system of Supplementary Note 5, the operating means is provided outside the storage means and is electrically connected to the connector, and the control means is provided outside or inside the storage means. By connecting the control means and the connector to each other via the first drive side wiring, and connecting the control means and the drive means to each other via the second drive side wiring, the operating means and the control means are connected to each other. Alternatively, since it can be installed in the storage means, the drive side wiring, the operating means, and the control means can be installed together in the body or the storage means. Therefore, it is not necessary to carry the control means and the operation means when performing the attachment/detachment work, so that it is easier to improve the efficiency of the attachment/detachment work as compared with the case where the operation means and the control means are connected using the power supply side wiring. Become.

According to the hoisting system described in appendix 6, the opening/closing machine is an electrically operated opening/closing machine controlled by the first control means, and the operating means for receiving the input of the hoisting signal and the winding means received by the operating means. Second control means for controlling the drive means based on the presence/absence of the input of the up signal, and when the second control means accepts the input of the hoist signal by the operating means, the stop signal Since the control signal is output to one control means, the switch control is performed by the first control means and the drive means control by the second control means at the same time as compared with the case where the stop signal is not output. Alternatively, it is possible to avoid a failure of the driving means.

According to the hoisting system described in appendix 7, since the power supply means is a commercial AC power supply of 100 V, it is relatively easy to secure electric power as compared with other power supply means, and thus the usability of the hoisting system is easily improved. ..

1 Switchgear 2 Body 3 Opening 4 Drive side wiring 4a First drive side wiring 4b Second drive side wiring 5 Power source side wiring 5a First power source side wiring 5b Second power source side wiring 6 First detection side wiring 7 First opening/closing Side wiring 8 Second opening/closing side wiring 9a Floor surface 9b Ceiling 10 Storage section 10a Lag 10b Lag opening 11 Drive side bearing plate 12 Drive side mounting piece 13 Driven side bearing plate 14 Case plate 20 Guide rail 30 Opening/closing body 31 Slat 33 Seat plate 40 Winding shaft 40a Driven side shaft part 41 Drive side bearing part 42 Winding shaft side sprocket 43 Transmission member 50 Opening machine 50a Connection plate 51 Input shaft 52 Output shaft 53 Opening machine side sprocket 54 Opening machine body 55 Manual operation part 60 Hoisting system 61 Drive part 61a First connection part 61b Second connection part 61c Third connection part 62 First connector part 63 Second connector part 64 Third connector part 65 Upper limit detection part 66 Frequency detection part 67 Connector storage part 67a Main body Part 67b Lid part 67c Locking part 68 Code reel 68a Wiring 69 Power supply part 70 Winding upper side control unit 71 Winding side operating part 71a Rotation direction changeover switch 71b Start switch 71c Stop switch 81 Upper and lower limit detecting part 82 Opening and closing side operating part 90 Opening and closing side control Unit 100 Switchgear 200 Switchgear 201 Wiring 210 Manual closing device H1 Workable position H2 Operable position M Maximum winding diameter of winding shaft

Claims (7)

A hoisting system for hoisting an opening/closing body for opening/closing an opening of a building through an opening/closing machine,
A drive means connected to the rotary shaft of the switch, the drive means electrically driving the switch;
A power supply unit that is provided outside the storage unit that stores the opening/closing member and that is attached to a drive-side wiring that is directly or indirectly connected to the drive unit and that supplies power to the drive unit. And a connector for detachably connecting the power supply side wiring directly or indirectly connected to,
The connector is arranged at a position where an operator located on the floor surface of the building can perform attachment/detachment work of the connector and the power supply side wiring,
Hoisting system. The connector is directly or indirectly attached to a portion of the body of the building located in the vicinity of the opening above the floor surface.
The winding system according to claim 1. A connector accommodating means for accommodating the connector,
The winding system according to claim 1 or 2. An operating unit that receives an input of a hoisting signal that instructs the hoisting of the opening/closing body by driving the driving unit,
Control means electrically connected to the operating means, the control means for controlling the drive means based on the presence or absence of the input of the hoisting signal by the operating means,
The power supply side wiring is
A first power supply side wiring located on the connector side,
A second power supply side wiring located on the power supply means side,
By connecting the control means and the connector to each other via the first power supply side wiring, and connecting the control means and the power supply means to each other via the second power supply side wiring, the power supply Side wiring, the operating means, and the control means can be carried,
The winding system according to any one of claims 1 to 3. An operation unit provided outside the storage unit and electrically connected to the connector, the operation unit receiving an input of a hoisting signal for instructing hoisting of the opening/closing body by driving the driving unit,
A control means which is provided outside or inside the storage means, and which controls the drive means based on whether or not the hoisting signal is input by the operation means,
The drive side wiring is
A first drive side wiring located on the connector side,
A second drive side wiring located on the drive means side,
The operation is performed by connecting the control means and the connector to each other via the first drive side wiring, and connecting the control means and the drive means to each other via the second drive side wiring. The means and the control means can be installed in the body of the building or the storage means,
The winding system according to any one of claims 1 to 3. The switch is an electric switch controlled by the first control means,
An operating unit that receives an input of a hoisting signal that instructs the hoisting of the opening/closing body by driving the driving unit,
Second control means for controlling the drive means based on the presence/absence of the input of the hoisting signal received by the operation means,
The second control means, when the input of the hoisting signal by the operation means is accepted, sends the stop signal for instructing to stop the control of the switchgear by the first control means to the first control signal. Output to the control means,
The winding system according to any one of claims 1 to 3. The power supply means is a commercial AC power supply of 100V,
The winding system according to any one of claims 1 to 6.

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