JP5603511B2 - Electric curtain rail - Google Patents

Description

  The present invention relates to an electric curtain rail that can be bent and cut, and can be easily fed.

  In the electric curtain opening / closing device described in Patent Document 1, a movable body (driving runner) including a curtain hanging portion and an electric motor travels in a hollow portion of the curtain rail extending along the longitudinal direction. A configuration in which the electric motor is fed by a feeding pattern extending along the line is disclosed.

  On the other hand, a bendable curtain rail made of a flexible material is known. For example, there are Patent Documents 2 and 3. The flexible curtain rail can be bent freely according to the shape of the installation location, and the length is also made of a flexible material so that it can be easily cut and adjusted at any location. is there.

Japanese Patent No. 4791600 Japanese Patent Laid-Open No. 10-43041 JP 2000-245618 A

  In an electric curtain rail such as that disclosed in Patent Document 1, a power supply pattern extends substantially over the entire length in order to supply power to a drive runner mounted with an electric motor. Therefore, a mechanism for supplying power to the power supply member to the curtain rail is required.

  In view of the above, an object of the present invention is to provide an electric curtain rail that is easily supplied with power in an electric curtain rail on which a drive runner equipped with an electric motor travels along the curtain rail.

  In order to achieve the above object, the present invention provides the following configuration. Note that the numbers in parentheses are reference numerals (only representative ones are shown) in the drawings showing corresponding embodiments described later. These reference numerals are attached for reference, and are not intended to be limited to the embodiments corresponding to the reference numerals.

The present invention described in claim 1 includes a curtain rail body,
A pair of electrically conductive feeding members (3) disposed over the entire length of the curtain rail body;
A drive that is mounted on the curtain rail body and is mounted on the electric motor (4a) that is fed by the pair of feeding members (3) and that is driven by the electric motor (4a) and travels along the curtain rail body Runner (4),
An electrode portion (7a) for supplying power to the pair of power supply members (3),
The first and second curtain rail bodies are disposed, and at least one of the curtain rails further includes a pair of power supply extension members (30) in addition to the pair of power supply members (3). It is an electric curtain rail.

The invention according to claim 2 is the electric curtain rail according to claim 1,
The first and second curtain rail bodies are arranged in series, and in addition to the pair of feeding members (3), each curtain rail body is further provided with a pair of feeding extension members (30). It is an electric curtain rail.

The invention according to claim 3 is the electric curtain rail according to claim 1,
One end of each of the pair of power supply extension members (30) in the first curtain rail main body is a second pair of electrodes of the electrode portion (7a) inserted into the first curtain rail main body. Electrically connected to each of (7a8),
The other end of the first curtain rail body is connected to the second curtain rail body by a connecting member (9),
The other end of each of the pair of power supply extension members (30) of the first curtain rail body is connected to each of the pair of power supply members (3) of the second curtain rail body by the connection member (9). It is an electric curtain rail characterized by being electrically connected to.

The invention according to claim 4 is the electric curtain rail according to claim 1 or 2,
An electric curtain rail characterized in that the curtain rail body can be cut at an arbitrary position, and the electrode portion (7a) can be attached to and detached from an end of the cut curtain rail body. is there.

The invention according to claim 5 is the electric curtain rail according to any one of claims 1 to 3,
The curtain rail body has an upper flange (2a) and a lower flange (2c) that are substantially H-shaped in cross-section perpendicular to the longitudinal direction, and the upper flange (2a) and the lower flange (2c). ) Between the web (2b)
The pair of power supply members (3) are disposed on the upper flange (2a) or the lower flange (2c) or the web (2b),
The drive runner (4) is disposed between a pair of drive wheels (4d) traveling on the upper surface of the lower flange (2c) and at least one of the electric motor (4a) and the pair of drive wheels (4d). An electric curtain rail comprising a rotation transmission mechanism (4c) arranged.

According to the first aspect of the present invention, the first and second curtain rail bodies (2B, 2B ') are arranged, and at least one of the curtain rail bodies has a pair of conductive electrodes arranged over the entire length. In addition to the power supply member (3), a pair of power supply extension members (30) is further provided. Therefore, power is supplied from one power supply member (3) to the first curtain rail (2B), and the second curtain rail (2B ') Can be fed via the feeding extension member (30).
According to the second aspect of the present invention, the first and second curtain rail bodies (2B, 2B ′) are arranged in series, and in addition to the pair of feeding members (3), the curtain rails are arranged in series. Furthermore, since a pair of power supply extension members (30) are provided, power can be supplied from the first curtain rail to the second curtain rail via the power supply member.

According to a third aspect of the present invention, the second pair of electrodes (7a8) are inserted into the pair of power supply extension members (30) of the first curtain rail body (2B) via the connection member (9). The second curtain rail main body (2B ′) is electrically connected to the pair of power supply members (3).
Therefore, electricity can be supplied from the first curtain rail body (2B) to the second curtain rail body (2B ′) via the power supply extension member (30) and the connection member (9).
In the above-described configuration, as described in claim 4, the curtain rail body (2A) can be cut at an arbitrary position, and the electrode with respect to the cut end of the curtain rail body (2A) When the part (7a) can be attached and detached, a curtain rail corresponding to the length of the window or the like to be arranged can be provided.

  In the above configuration, as described in claim 5, the curtain rail body 2A has a substantially H-shaped cross section, and the drive runner 4 travels on the upper surface of the lower flange 2c, and the electric motor In the case of including the rotation transmission mechanism 4c disposed between 4a and the pair of drive wheels 4d, the stability is good and power feeding is easy.

FIG. 1 is an external perspective view partially showing an embodiment of a bendable electric curtain rail of the present invention. 2A is a schematic cross-sectional view of a portion where the drive runner exists in the curtain rail shown in FIG. 1, and FIG. 2B is a side view. 3A is a schematic cross-sectional view of a portion where the driven runner exists in the curtain rail shown in FIG. 1, and FIG. 3B is a side view. FIG. 4 is a plan view schematically showing the overall arrangement of an example of application to a single curtain. FIG. 5A is a schematic perspective view of the drive control device 7A, and FIG. 5B is an external perspective view of an example of the remote controller RC. FIG. 6 is a perspective view of a state in which the drive control device is inserted into the end portion of the curtain rail body. 7A is a front view of the drive control device shown in FIG. 5, and FIG. 7B is a cross-sectional view of the drive control device inserted into the end of the curtain rail body. FIG. 8A is a side view showing an example of the end cap shown in FIG. 4, and FIG. 8B is a cross-sectional view of FIG. FIG. 9 is a configuration diagram schematically showing the internal configuration of the drive control device and the electrical connection relationship between the drive control device and the power supply member of the curtain rail body. FIG. 10 is a perspective view showing a modification of the first embodiment. FIG. 11 is a plan view schematically showing the overall arrangement of an application example of the curtain rail of the second embodiment to a double curtain. FIG. 12 is a cross-sectional view of the curtain rail body of the second embodiment. 13A is a cross-sectional view along the longitudinal direction of the periphery of the connecting member shown in FIG. 11, FIG. 13B is a B cross-sectional view of FIG. 13A, and FIG. FIG. 14A is a front view of the drive control device shown in FIG. 11, and FIG. 14B is a cross-sectional view perpendicular to the longitudinal direction in a state where the drive control device is inserted into the end of the curtain rail body. is there. FIG. 15 schematically shows the internal configuration of the drive control device and the electrical connection relationship between the drive control device, the power supply member and power supply extension member of the first curtain rail body, and the power supply member of the second curtain rail body. It is the block diagram shown in. FIG. 16 is a cross-sectional view schematically showing a modified form of the drive runner shown in FIG. FIG. 17 is a cross-sectional view schematically showing a modified form of the curtain rail body shown in FIG. 2 and a modified form of the drive runner. FIG. 18 is a cross-sectional view schematically showing still another modification of the drive runner shown in FIG. FIG. 19 is a cross-sectional view schematically showing still another modification of the curtain rail body and the drive runner shown in FIG. 20 is a cross-sectional view schematically showing still another modification of the curtain rail body and the drive runner shown in FIG. FIG. 20 is a top view schematically showing a curved curtain rail body.

  Hereinafter, some embodiments of a bendable electric curtain rail of the present invention will be described with reference to an example shown in the drawings. In the drawings illustrating the embodiments, the same or corresponding constituent elements are denoted by the same or similar reference numerals. About the component which attached | subjected the same or similar code | symbol, the description about embodiment shown later which overlaps with description about embodiment shown previously may be abbreviate | omitted. Further, when a plurality of identical components are present in one drawing, only one of them is basically denoted by a reference numeral.

[1] Basic Configuration of First Embodiment FIG. 1 is an external perspective view partially showing one embodiment of a bendable electric curtain rail of the present invention.

  A bendable electric curtain rail (hereinafter simply referred to as “curtain rail”) 1A is mounted on a curtain rail main body 2A formed of a flexible material, and is mounted on the curtain rail main body 2A and travels along the longitudinal direction. It has a drive runner 4 and a driven runner 5. The curtain rail 1A has a basically symmetrical shape in a cross section perpendicular to the longitudinal direction (hereinafter, the symmetrical elements are expressed as “a pair” and only one symbol is shown). . The curtain rail body 2A is fixed along the wall using the fixture 6A, or is fixed along the ceiling using the fixture 6B.

  A suitable shape of the curtain rail main body 2A has a substantially H-shaped cross section (horizontal substantially H-shaped) as shown in the figure, and includes an upper and lower flange portion and a web portion connecting the centers. This shape is easy to bend in a horizontal plane. The material of the curtain rail body 2A is, for example, a plastic extruded material such as polyethylene or polypropylene. Further, it is preferable to embed a metal band core material (not shown) in the web portion, which makes it easier to maintain a specific shape after deformation. As shown in the figure, the curtain rail body 2A can be bent in the horizontal direction while maintaining its cross-sectional shape. The plastic curtain rail body 2A is preferable because it secures flexibility and at the same time ensures electrical insulation. Moreover, it can cut | disconnect easily compared with a metal curtain rail.

  Since the detailed configuration will be described with reference to FIG. 2, only the outline will be described with reference to FIG. On the curtain rail body 2A, a pair of belt-shaped power supply members 3 are arranged over the entire length. The drive runner 4 is supplied with power from the pair of power supply members 3 via the pair of conductive rollers 4e. Furthermore, it is electrically connected to the electric motor 4a via a pair of conductive springs 4f, thereby supplying power to the electric motor 4a. The electric motor 4a is suspended directly under the curtain rail body 2A. The drive runner 4 has a pair of drive wheels 4d placed in a running groove on the upper surface of the lower flange. The rotation of the rotating shaft of the electric motor 4a is transmitted to each drive wheel 4d via the rotation transmission mechanisms 4c on both sides. Thereby, a pair of drive wheel 4d rotates and the drive runner 4 can drive | work. It is preferable that unevenness (for example, a triangular tooth shape) is formed on the bottom surface of the running groove to prevent slipping. A hanging portion 4b for hanging a curtain (not shown) is attached to the center of the electric motor 4a.

  The driven runner 5 also has a pair of driven wheels placed in a running groove on the upper surface of the lower flange. The driven runner 5 travels according to the drive runner 4. Although only one driven runner 5 is illustrated, there are usually a plurality of driven runners 5 combined with one drive runner 4. One curtain is suspended under a series of runners composed of one drive runner 4 and a plurality of driven runners 5. When the curtain is opened, the driven runner 4 is driven to travel, and the driven runner 5 is pulled through the suspended curtain to travel. When the curtain is closed, the driven runner 4 is driven to travel and the driven runner 5 is pushed to travel.

  2A is a schematic cross-sectional view perpendicular to the longitudinal direction in a portion where the drive runner 4 is present in the curtain rail 1A shown in FIG. 1, and FIG. 2B is a side view.

  The curtain rail body 2A includes a substantially flat upper and lower flanges 2a and 2c arranged in parallel to each other, and a substantially flat web 2b that connects between the midpoints of the upper flange 2a and the lower flange 2c. To do. In this embodiment, the pair of power supply members 3 are disposed on the upper flange 2a. The edges on both sides of the upper flange 2a are folded inward in a U shape to form a recess 2a1. In the recess 2a1, a strip-shaped power supply member 3 that is a conductor is disposed horizontally. The power feeding member 3 is fixed to the curtain rail body 2A with an appropriate adhesive or the like. The position of the power supply member 3 is not limited to the illustrated example. However, since the power feeding member 3 extends over the entire length of the curtain rail body 2A, it is preferable to arrange the power feeding member 3 at a position that is difficult to touch from the outside in order to prevent an electric shock accident. Preferably, a pair of running grooves 2c1 are formed in two upper surfaces of the lower flange 2c.

  The shape and configuration of the cross section perpendicular to the longitudinal direction of the curtain rail body 2A are the same at any position in the longitudinal direction. The curtain rail body 2A can be cut at any position according to the installation location. Even if the curtain rail body 2A is cut at any position, the end of the cut end has the same configuration. The same applies to other embodiments below. Before the curtain rail body 2A is cut into a predetermined length, for example, it has a length of several meters to several tens of meters, and is transported and sold in a state of being wound like a winding coil of an electric wire. Do.

  The drive runner 4 includes a pair of drive wheels 4d that travel on the upper surface of the lower flange 2c. In the illustrated example, a lead wire (or rod-shaped conductor) 4g for electrical connection is disposed inside the drive shaft 4d1 of the drive wheel 4d. The pair of conductive rollers 4 e made of a conductive material can roll on the pair of power supply members 3 when the drive runner 4 travels, and power is supplied by contacting the power supply members 3. The pair of conductive rollers 4e is electrically connected to a pair of conductive springs 4f made of a conductive material. The conductive spring 4f functions as a shock absorber when the drive wheel 4d travels simultaneously with the electrical connection. The conductive spring 4f is electrically connected to the pair of lead wires 4g. The lead wire 4g passes through the pair of insulating covers 4h, passes through the pair of motor shafts 4a1, and is electrically connected to the electric motor 4a. The direction and speed of rotation of the electric motor 4a are controlled by the polarity and magnitude of the voltage supplied from the pair of power supply members 3 to the electric motor 4a.

  Note that each conductive member to which a predetermined voltage is applied is in a position where there is no possibility of being touched by the hand from the outside, or although not shown, it is directly covered with an appropriate insulator or is not It is assumed that measures against electric shock such as being covered with a cover (insulating cover 4h, etc.) are taken.

  The rotation of the electric motor 4a is taken out from the motor shafts 4a1 on both sides and transmitted to the pair of drive wheels 4d via the rotation transmission mechanism. Each rotation transmission mechanism in the embodiment of FIG. 2 is composed of two gears 4c1 and 4c2 meshed vertically. The pair of drive wheels 4d travels in the pair of travel grooves 2c1 at a predetermined direction and speed. In FIG. 2, the gear of the rotation transmission mechanism is illustrated in an exposed state, but it is preferable to cover with a suitable cover (the same applies to other embodiments below).

  A hook hole 4b1 for hooking a curtain hook is formed in the vicinity of the lower end of the hanging part 4b.

  As is obvious from the illustrated configuration, the pair of driving wheels 4d and the pair of driven wheels 5d can travel along the curtain rail main body without dropping off even without the traveling groove 2c1. Although it is preferable to provide the running groove 2c1, it may not be provided. The same applies to other embodiments below.

  FIG. 3A is a schematic cross-sectional view perpendicular to the longitudinal direction in a portion where the driven runner 5 exists in the curtain rail 1A shown in FIG. 1, and FIG. 3B is a side view.

  The driven runner 5 includes a pair of driven wheels 5d. The pair of driven wheels 5d is disposed in the pair of traveling grooves 2c1. The driven shaft 5d1 of each driven wheel 5d is rotatably supported. Each driven wheel 5d is connected to a suspended portion 5b suspended directly below the curtain rail body 2A via each connecting member 5h. A hook hole 5b1 is provided in the vicinity of the lower end of the hanging part 5b for hooking a curtain hook.

[2] Application Example of First Embodiment to Single-Opening Curtain An application example of the curtain rail 1A of the first embodiment shown in FIGS.

  FIG. 4 is a plan view schematically showing the overall arrangement of an application example of the curtain rail 1A to a one-sided curtain. The curtain rail body 2A in the curtain rail 1A is bent after being cut into a predetermined length in accordance with a curved shape such as a bay window, for example. One leading drive runner 4 and a plurality of following driven runners 5 are mounted on the curtain rail body 2A. A drive control device 7A is attached to one end of the curtain rail body 2A, and an end cap 8 is attached to the other end. The drive control device 7A and the end cap 8 are both detachable. Each runner 4 and 5 is inserted from either end of the curtain rail body 2A before the drive control device 7A and the end cap 8 are mounted. After the drive control device 7A and the end cap 8 are mounted, the runners 4 and 5 do not fall off the curtain rail body (the same applies to the following embodiments).

  The drive control device 7A performs electrical connection between a circuit unit that generates an appropriate voltage and current to be supplied to the power supply member of the curtain rail body 2A by converting an external AC power supply and the power supply member of the curtain rail body 2A. The electrode part is provided. The remote controller RC wirelessly transmits a control signal to the drive control device 7A.

  FIG. 5A is a schematic perspective view of an example of the drive control device 7A, and FIG. 5B is an external perspective view of an example of the remote controller RC.

  As shown in FIG. 5A, the drive control device 7A has one housing in which the electrode portion 7a and the circuit portion 7b are integrated. The circuit unit 7b includes a circuit having a configuration illustrated in FIG. 9 described later. An external AC power supply line 7c is connected to the circuit unit 7b. As an example, a power supply circuit (adapter) 7b1 of FIG. 9 described later is provided between the supply line 7c and the circuit unit 7b. Although not shown, the electrical output of the circuit portion 7b (outputted to the pair of output terminals) is electrically connected to the pair of electrodes 7a2 of the electrode portion 7a.

  The electrode portion 7a includes a housing whose bottom wall center is open. The pair of bottom walls 7a1 extending inward from both side walls rises with an open portion at the center interposed therebetween, and is further folded outward to form a pair of recesses. A pair of belt-like electrodes 7a2 are disposed on the lower surface of the portion folded outward. The electrode 7a2 is fixed with an appropriate adhesive or the like. The entire casing of the electrode portion 7a does not need to be an insulator, but an insulator is appropriately disposed so as to ensure electrical insulation of the electrode 7a2 so as not to cause a short circuit due to at least the electrode 7a2.

  The electrode portion 7a further includes a base plate 7a3, a spring seat plate 7a4, a pressing spring 7a5, a screw 7a6, and a tightening handle 7a7 for fixing to the end of the curtain rail body. These will be described in detail later with reference to FIG.

  The remote controller RC shown in FIG. 5B transmits a control signal wirelessly to the drive control device 7A. For example, a switch “O” for starting the operation of opening the curtain, a switch “C” for starting the operation of closing the curtain, and a switch “S” for stopping the operation of the curtain are provided.

  In the example of the drive control device 7A of FIG. 5A, a wireless reception circuit 7b2 of FIG. 9 described later is incorporated in the circuit unit 7b. The wireless reception circuit 7b2 has a function of receiving a signal from the remote controller RC.

  FIG. 6 is a perspective view of a state in which the drive control device 7A shown in FIG. 5A is inserted into the end of the curtain rail body 2A. The curtain rail body 2A can be cut at an arbitrary position. And the electrode part 7a of 7 A of drive control apparatuses can be inserted in the edge part cut | disconnected in any position. It can also be pulled out and removed. Thus, the power supply means for the curtain rail body 2A can be attached very simply.

  It should be noted that at least the electrode portion 7a is sufficient as an element that can be directly attached to and detached from the end portion of the curtain rail body 2A. Therefore, as a modification, the circuit portion 7b can be separated from the electrode portion 7a and installed at a different position. In that case, it is necessary to electrically connect the circuit portion 7b and the electrode portion 7a by appropriate wiring.

  7A is a front view of the drive control device 7A shown in FIG. 5A, and FIG. 7B is a longitudinal view of the drive control device 7A inserted into the end of the curtain rail body 2A. It is a vertical sectional view.

  When the drive control device 7A is attached to the end of the curtain rail body 2A, it is inserted until the tip of the curtain rail body 2A reaches the innermost part of the electrode portion 7a of the drive control device 7A. After the insertion is completed, as shown in the cross-sectional view of FIG. 7B, the recessed portion of the folded portion of the bottom wall 7a1 of the electrode portion 7a of the drive control device 7A and the recessed portion of the edge of the upper flange 2a of the curtain rail body 2A 2a1 is fitted. In this fitting portion, the pair of electrodes 7a2 of the electrode portion 7a and the pair of power supply members 3 of the curtain rail body 2A are in surface contact.

  At the time of insertion, the base plate 7a3 of the electrode portion 7a is placed on the upper surface of the upper flange 2a of the curtain rail body 2A. A screw 7a6 extends upward from the base plate 7a3, and a handle 7a7 is screwed to the upper end of the screw 7a6. A pressing spring 7a5 is disposed between the handle 7a7 and the spring seat plate 7a4. When the handle 7a7 is turned and moved downward, the pressing spring 7a5 is compressed, and the spring seat plate 7a4 pushes down the casing of the electrode portion 7a. Thereby, the electrode 7a2 is pressed against the power supply member 3, and a reliable electrical connection is obtained. When removing the drive control device 7A, the handle 7a7 is turned in the reverse direction to loosen it. The configuration of the electrode portion 7a is not limited to the illustrated example, and various forms are possible for forming an electrical connection between the pair of electrodes 7a2 and the pair of power supply members 3.

  FIG. 8A is a side view showing an example of the end cap 8 shown in FIG. 4, and FIG. 8B is a cross-sectional view taken along line A in FIG.

  As shown in FIGS. 8 (a) and 8 (b), the end cap 8 has a peripheral wall 8a having a rectangular outer shape, and a recess into which the end of the curtain rail body 2A can be inserted is formed on one end face. Has been. The other end surface is a closed wall 8b. As shown in FIG. 8B, the bulging portion 8b from the side wall of the recess into which the curtain rail body 2A is inserted may be fitted in the space between the upper flange and the lower flange of the curtain rail body 2A. Good. Thereby, the edge part of 2 A of curtain rail main bodies is hold | maintained stably. Note that the end cap 8 does not need to be an insulator as a whole, but an insulator is appropriately disposed so as to ensure electrical insulation of the power supply member 3 so that at least a short circuit due to the power supply member 3 does not occur.

  FIG. 9 is a configuration diagram schematically showing an example of the internal configuration of the drive control device 7A and the electrical connection relationship between the drive control device 7A and the power feeding member 3 of the curtain rail body 2A. A white arrow represents an electrical connection by insertion.

  The circuit unit 7b supplies power to an electric motor (either a direct current motor or an alternating current motor) mounted on a drive runner in a power supply circuit 7b1 (in the illustrated example, an adapter disposed outside the housing) to which external AC power is supplied. Conversion is performed so that power (voltage and current) to be obtained is obtained. The generated supply power is input to the curtain control circuit 7b3. The wireless control signal from the remote controller RC is received by the wireless reception circuit 7b2 (in the illustrated example, built in the casing), and the received control signal is input to the curtain control circuit 7b3.

  The pair of output terminals of the curtain control circuit 7b3 is connected to the pair of electrodes 7a2 of the electrode portion 7a. The curtain control circuit 7b3 converts the supply power input from the power supply circuit 7b1 based on the received control signal so as to have an appropriate polarity and voltage, and then outputs the output power to the output terminal or stops the output. To do. The polarity determines the rotation direction of the electric motor, that is, the direction in which the drive runner travels, and the voltage determines the rotation speed of the electric motor, that is, the travel speed of the drive runner. The output on / off determines whether the drive runner is running or stopped.

  The remote controller RC preferably has a wireless specification (including all signal propagation means other than wired communication and may have any signal form and frequency band such as radio waves, electromagnetic waves, laser light, and infrared rays). However, as a modification, a remote controller connected to the drive control device 7A by wire may be attached to a wall or the like (the same applies to the following embodiments).

  Also, two curtain rails 2A of the first embodiment are prepared, one end of each is connected via an appropriate insulator, and the electrode portion 7a of the drive control device 7A is connected to the other end of each. If each is mounted, it is possible to configure a double curtain that can be opened and closed separately on the left and right. However, in that case, since two drive control devices 7A are required, the double-opening curtain configuration by the curtain rail of the second embodiment described later is more preferable.

FIG. 10 is a perspective view showing a modification of the first embodiment.
FIG. 10 shows a state in which the modified drive control device 7A1 is inserted into the end of the modified curtain rail body 2A1. The difference between the drive control device 7A1 and the drive control device 7A of FIG. 5 is that the wireless reception circuit 7b2 is not built in the circuit unit 7b and is separated from the housing of the drive control device 7A1. . In the illustrated example, the wireless reception circuit 7b2 includes an individual casing. The housing of the radio reception circuit 7b2 can slide along the upper surface of the upper flange 2a of the curtain rail body 2A1 (see the white arrow). Preferably, a pair of slide grooves 2a7 are formed on the upper surface of the upper flange 2a of the curtain rail body 2A1, while a pair of ridges 7b21 that fit into the slide grooves 2a7 are formed on the bottom surface of the housing of the radio reception circuit 7b2. Has been. Thereby, the wireless reception circuit 7b2 can slide smoothly. Further, a conductor 2a8 is embedded in each bottom surface of the pair of slide grooves 2a7. The pair of conductors 2a8 serve as signal lines for transmitting the signal received by the wireless reception circuit 7b2 from the remote controller to the circuit unit 7b of the drive control device 7A1. Although not shown, the end portion of the conductor 2a8 is electrically connected to a circuit built in the circuit portion 7b.

  When the radio receiving circuit 7b2 requires a power source for signal processing therein, a battery is built in the housing or another pair of power source conductors are arranged on the bottom surface of the slide groove 2a7. . Alternatively, the wireless reception circuit 7b2 may be supplied with power by being electrically connected to the power supply member 3 of the curtain rail body 2A1 through appropriate wiring at the installation location.

  By separating the radio reception circuit 7b2 in this way, the radio reception circuit 7b2 can be installed at a position where the signal from the remote controller can be reliably received. For example, when there is a shield between the drive control device 7A1 and the remote controller, the wireless reception circuit 7b2 is moved to the optimum position and installed. Since the length of the curtain rail body 2A1 can be freely set, a very long case can be considered. It is particularly effective in such a case.

  If the position of the wireless reception circuit 7b2 is determined, an appropriate insulating member 2a9 may be fitted into the slide groove 2a7 other than the location where the wireless reception circuit 7b2 exists so that the signal line 2a8 is not exposed. Is preferred.

  As still another modification, the radio reception circuit 7b2 may be installed not at the curtain rail body 2A1 but at an arbitrary place optimal for receiving signals. In that case, the wireless reception circuit 7b2 and the drive control device 7A1 are electrically connected by wiring for signal transmission and power supply.

  The modification in which the wireless reception circuit described with reference to FIG. 10 can be separated and installed at the optimum position can be similarly applied to the following second embodiment.

[3] Second Embodiment and Application Example to Double-Opening Curtain The second embodiment of the curtain rail of the present invention is applicable to a double-opening curtain. The second embodiment will be described by explaining an application example to a double curtain.

  FIG. 11 is a plan view schematically showing the overall arrangement of an application example of the curtain rail 1B of the second embodiment to a double curtain.

  In the case of a double curtain, two curtain rail bodies 2B and 2B 'are used. These are curtain rail bodies having the same configuration, and two pieces having a predetermined length can be cut out from one curtain rail body. The lengths are not necessarily the same. Each is bent according to the curved shape of the bay window or the like. The curtain rail body 2B has one leading drive runner 4 and a plurality of following driven runners 5, and the curtain rail body 2B ′ has one leading drive runner 4 ′ and a plurality of following driven runners 5 ′. Each is attached.

  A drive control device 7B is attached to one end of the curtain rail body 2B. The other end of the curtain rail main body 2B is connected to one end of the curtain rail main body 2B 'via a connecting member 9. An end cap 8 shown in FIG. 8 is attached to the other end of the curtain rail body 2B ′. The drive control device 7B, the connection member 9, and the end cap 8 are all detachable.

  The drive control device 7B converts an external AC power source to generate appropriate voltages and currents to be supplied to the feeding members of the curtain rail bodies 2B and 2B ′, and the curtain rail bodies 2B and 2B ′. And an electrode portion for performing electrical connection with the power supply member. However, in this case, since the curtain rail body 2B 'is not directly connected to the drive control device 7B, a mechanism for supplying power to the curtain rail body 2B' is required. This is different from the first embodiment described above. In the second embodiment, it is possible to supply power to the curtain rail body 2B 'that is not directly connected by one drive control device 7B.

  The remote controller RC wirelessly transmits a control signal to the drive control device 7B. In the second embodiment, the remote controller RC can control each of the right curtain and the left curtain independently.

  FIG. 12 is a cross-sectional view perpendicular to the longitudinal direction of the curtain rail bodies 2B and 2B ′ according to the second embodiment.

  The second embodiment is different from the first embodiment in that the curtain rail bodies 2B and 2B 'include a pair of power supply extension members 30. In the illustrated example, the pair of power supply extension members 30 are band-shaped conductors, and are disposed and fixed on the lower surface of the upper flange. However, the shape and position of the power supply extension member 30 are not limited to this example. Any shape and position may be used as long as they are insulated from the pair of power supply members 3 and extend over the entire length of the curtain rail bodies 2B and 2B '. However, it shall be a position that does not hinder the running of each runner and ensure insulation from the surroundings. By providing the power supply extension member 30, it is possible to supply power to the power supply member 3 of the curtain rail body that is not directly connected to the drive control device 7B.

  13A is a cross-sectional view along the longitudinal direction in the vicinity of the connecting member 9 shown in FIG. 11, FIG. 13B is a B cross-sectional view of FIG. 13A, and FIG. It is C sectional drawing of a).

  As shown in FIG. 13 (a), the connecting member 9 has a peripheral wall 9a having a rectangular outer shape, and concave portions into which the end portions of the curtain rail bodies 2B and 2B ′ can be inserted are formed on both end surfaces. Has been. There is a central wall 9b having electrical insulation between the two recesses. A conductor piece 9e is provided so as to penetrate the central wall 9b. One end 9e1 of the conductor piece 9e protrudes into one recess, and the other end 9e2 protrudes into the other recess.

  As shown in FIG. 13B, one end 9e1 of the connection member 9 is in contact with and electrically connected to the power supply extension member 30 of the curtain rail body 2B inserted into the recess. Preferably, the end portion 9e1 has an elastically deformable shape, and makes contact with the feeding extension member 30 by applying a pressing force.

  Similarly, as shown in FIG. 13C, the other end 9e2 of the connection member 9 is in contact with and electrically connected to the power supply member 3 'of the curtain rail body 2B' inserted into the recess. Preferably, the end portion 9e2 has an elastically deformable shape and makes contact with the feeding member 3 'by applying a pressing force.

  In this manner, the power supply extension member 30 of the curtain rail body 2B and the power supply member 3 'of the curtain rail body 2B' are electrically connected by the conductor piece 9e.

  Since the curtain rail body 2B 'has the same configuration as the curtain rail body 2B, the curtain rail body 2B' includes the power supply extension member 30 '. However, the curtain rail body 2B' is not used in this case. For example, as another example, in FIG. 11, when the drive control device 7B and the end cap 8 are mounted in reverse, the connecting member 9 is also connected in the reverse direction. In that case, the power supply extension member 30 ′ of the curtain rail body 2 </ b> B ′ and the power supply member 3 of the curtain rail body 2 </ b> B are electrically connected.

  14A is a front view of the drive control device 7B shown in FIG. 11, and FIG. 14B is perpendicular to the longitudinal direction of the drive control device 7B inserted into the end of the curtain rail body 2B. It is sectional drawing.

  As shown in FIG. 14A, in the drive control device 7B, a pair of electrodes 7a2 are arranged and fixed inside the concave portion of the folded portion of the bottom wall 7a1 of the electrode portion 7a. The electrode 7a2 is the same as in the first embodiment. In the second embodiment, another pair of electrodes 7a8 is arranged and fixed on the upper surface of the folded portion of the bottom wall 7a1.

  When the drive control device 7B is attached to the end of the curtain rail body 2B, the drive control device 7B is inserted until the tip of the curtain rail body 2B reaches the innermost part of the electrode portion 7a of the drive control device 7B. As shown in the cross-sectional view of FIG. 14B, the recessed portion of the folded portion of the bottom wall 7a1 of the electrode portion 7a of the drive control device 7B and the recessed portion 2a1 at the edge of the upper flange 2a of the curtain rail body 2B are fitted. doing. In this fitting portion, the pair of electrodes 7a2 of the electrode portion 7a and the pair of power supply members 3 of the curtain rail body 2B are in surface contact. Further, the pair of electrodes 7a8 of the electrode portion 7a and the pair of power supply extension members 30 of the curtain rail main body are in surface contact.

  The pressing and fixing means 7a3, 7a4, 7a5, 7a6, and 7a7 provided on the electrode portion 7a of the drive control device 7B are the same as the drive control device 7A described in FIG. In the case of the configuration of FIG. 14B, the pressing and fixing means acts in a direction away from the connection between the electrode 7 a 8 and the power supply extension member 30. Therefore, for example, the electrode 7a8 is attached to the elastic material 7a9 having an elliptical cross section. Thereby, when the electrode portion 7a is inserted, the elastic material 7a9 is compressed, and even if the pressing and fixing means is applied, the electric force in the pressed state between the electrode 7a8 and the power supply extension member 30 by the restoring force of the elastic material 7a9. To ensure proper contact.

  The configuration of the electrode portion 7a is not limited to the example shown in the figure, and is to form an electrical connection between the pair of electrodes 7a2 and the pair of power supply members 3 and an electrical connection between the pair of electrodes 7a8 and the pair of power supply extension members 30. Various forms are possible.

  FIG. 15 shows an example of the internal configuration of the drive control device 7B, and the electrical connection between the drive control device 7B, the feeding member 3 and the feeding extension member 30 of the curtain rail body 2B, and the feeding member 3 ′ of the curtain rail body 2B ′. It is the block diagram which showed the connection relationship typically. A white arrow represents an electrical connection by insertion.

  The circuit unit 7b supplies power to an electric motor (either a direct current motor or an alternating current motor) mounted on a drive runner in a power supply circuit 7b1 (in the illustrated example, an adapter disposed outside the housing) to which external AC power is supplied. Conversion is performed so that power (voltage and current) to be obtained is obtained. The generated supply power is input to the right curtain control circuit 7b3 and the left curtain control device 7b4, respectively. A wireless control signal from the remote controller RC is received by the wireless reception circuit 7b2, and the received control signals are input to the right curtain control circuit 7b3 and the left curtain control device 7b4, respectively.

  The pair of output terminals of the right curtain control circuit 7b3 is connected to the pair of electrodes 7a2 of the electrode portion 7a. The pair of electrodes 7a2 are connected to the pair of power feeding members 3 of the curtain rail body 2B, thereby supplying driving power to the right curtain driving runner.

  The pair of output terminals of the left curtain control circuit 7b4 is connected to the pair of electrodes 7a8 of the electrode portion 7a. The pair of electrodes 7a8 is connected to the pair of power supply extension members 30 of the curtain rail body 2B. The pair of power supply extension members 30 of the curtain rail body 2 </ b> B are connected to one end 9 e 1 of the conductor piece 9 e of the connection member 9. The other end 9e2 of the conductor piece 9e of the connecting member 9 is connected to a pair of power supply members 3 'of the curtain rail body 2B'. Thereby, drive power is supplied to the drive runner for the left curtain.

  Each of the right curtain control circuit 7b3 and the left curtain control circuit 7b4 converts the supply power input from the power supply circuit 7b1 based on the received control signal so as to have an appropriate polarity and voltage, and outputs the converted power to the output terminal. Or stop the output. The polarity determines the rotation direction of the electric motor, that is, the direction in which the drive runner travels, and the voltage determines the rotation speed of the electric motor, that is, the travel speed of the drive runner. The output on / off determines whether the drive runner is running or stopped. As a result, the right curtain and the left curtain can be controlled to open and close independently.

  The remote controller RC transmits a control signal wirelessly to the drive control device 7B. For example, the switch “R / L” for selecting whether to operate the right curtain or the left curtain, the switch “O” for starting the curtain opening operation, the switch “C” for starting the curtain closing operation, and the curtain operation A switch “S” is provided to stop the operation.

[4] Other Examples of Curtain Rail Main Body or Drive Runner FIG. 16 is a cross-sectional view schematically showing a modified form of the drive runner 4 shown in FIG. In the modified drive runner 4A, the rotation transmission mechanism between the electric motor 4a and the pair of drive wheels 4d, 4d 'is provided only on one drive wheel 4d, and not provided on the other drive wheel 4d'. The other drive wheel 4d 'travels as the one drive wheel 4d is driven.

  FIG. 17 is a cross-sectional view schematically showing still another modification of the curtain rail body 2A and the drive runner 4 shown in FIG. In the modified curtain rail body 2C, the pair of power supply members 3 are arranged in a recess formed in the lower flange 2c. Each conductive roller 4e of the drive runner 4B is also in contact with each power supply member 3 in each recess. The drive runner 4B in a modified form is configured such that the rotation transmission mechanism between the electric motor 4a and the pair of drive wheels 4d is composed of two gears 4j1, 4j2 and a toothed belt 4k spanned between them. Yes. As another form, you may comprise with two pulleys and a belt.

  FIG. 18 is a cross-sectional view schematically showing still another modification of the drive runner 4 shown in FIG. In the modified drive runner 4C, the rotation transmission mechanism between the electric motor 4a and the pair of drive wheels 4d is constituted by bevel gears 4m1, 4m2, 4m3, and 4m4.

  FIG. 19 is a cross-sectional view schematically showing still another modification of the curtain rail body 2A and the drive runner 4 shown in FIG. In the modified curtain rail body 2D, one of the pair of power supply members 3 and 3 'is disposed in one recess formed in the upper flange 2a, and the other in one recess formed in the lower flange 2c. Is arranged. The pair of conductive rollers 4e, 4e 'is also in contact with each power supply member in each recess. The lead wires 4g and 4g 'electrically connected to the respective conductive rollers are connected to the electric motor 4a through the insulating cover 4h. In the modified drive runner 4D, two gears 4j1 and 4j2 that are rotation transmission mechanisms and a toothed belt 4k spanned between them are provided only on one side.

FIG. 20 is a cross-sectional view schematically showing still another modification of the curtain rail body 2A and the drive runner 4 shown in FIG. In the modified curtain rail body 2E, the pair of power supply members 3, 3 ′ is disposed at the center of the web 2b. The pair of conductive rollers 4e and 4e 'in the modified drive runner 4E is in contact with each power supply member in each recess provided in the web 2b.
As shown in FIG. 21, when the curtain rail bodies 2A to 2E are curved, the outside of the curved portion is expanded and the inside is compressed. For this reason, in the curtain rail bodies 2A to 2D, it is necessary to form the pair of power feeding members 3, 3 ′ from a material that can withstand expansion and compression.
On the other hand, in the curtain rail main body 2E, the pair of power feeding members 3, 3 ′ are arranged in the center of the web 2b, so that the curtain rail main body 2E may be extended or compressed even if it is curved. Absent. For this reason, a pair of electric power feeding members 3 and 3 'can be formed with a material weak to expansion | extension and compression.

[5] Supplement The illustrated configuration described above is an example of each embodiment, and is not limited to the illustrated configuration. For example, the shape of the curtain rail body in each embodiment, the position of the feeding member, the position of the feeding extension member, the shape of the runner, the number of driving wheels and driven wheels (at least two for one runner, (For example, it may be four or six), and the configurations of the contact mechanism, the drive control device, and the like may have various modifications. Any combination with other embodiments is possible as long as the functions unique to each embodiment are not impaired.

  In 1st Embodiment and 2nd Embodiment, the electric power feeding member was provided in the position which is not exposed on a curtain rail main body in consideration of the electric shock accident. However, the present invention also includes a case where the pair of power supply members are installed on the upper surface of the lower flange of the curtain rail body (including the case where the curtain member is installed in the running groove). In that case, the drive wheel of the drive runner is a conductor, power is supplied from the power supply member to the drive wheel, and power can be supplied from the drive wheel to the electric motor by electrically connecting the drive wheel and the electric motor. it can.

  Finally, for reference, the electrode part detachable from the end of the curtain rail body in the present invention can be applied to a curtain rail body that is not bendable. For example, when the linear or predetermined curved shape itself is an invariable curtain rail body and can be freely cut for length adjustment, the electrode unit of the present invention can be used. Furthermore, the electrode part of the present invention can be used for a curtain rail body that is not cuttable.

1A, 1B: Flexible electric curtain rail 2A, 2A1, 2B, 2C, 2D, 2E: Curtain rail body 2a: Upper flange, 2a1: Upper flange recess, 2b: Web, 2c: Lower flange, 2c 1: Traveling groove
3: Power supply member 30: Power supply extension member 4, 4A, 4B, 4C, 4D, 4E: Drive runner 4a: Electric motor, 4a1: Motor shaft, 4b: Suspension, 4b1: Hook hole, 4c: Rotation transmission mechanism, 4c1 4c2: Gear, 4d: Drive wheel, 4d1: Drive shaft, 4e: Conductive roller, 4f: Conductive spring, 4g: Lead wire, 4h: Insulation cover, 4j1, 4j2: Gear, 4k: Toothed belt, 4m1, 4m2 4m3, 4m4: bevel gear 5: driven runner 6A, 6B: fixture 7A, 7B: drive control device 7a: electrode portion, 7a1: bottom wall, 7a2: electrode, 7a3: base plate, 7a4: spring seat plate, 7a5 : Pressing spring, 7a6: Screw, 7a7: Tightening handle, 7a8: Electrode, 7b: Circuit part, 7b1: Power supply circuit, 7b2: Radio receiving circuit, 7c: External AC power supply : End cap 9: connecting member RC: remote controller

Claims (5)

Curtain rail body,
A pair of electrically conductive feeding members (3) disposed over the entire length of the curtain rail body;
A drive that is mounted on the curtain rail body and is mounted on the electric motor (4a) that is fed by the pair of feeding members (3) and that is driven by the electric motor (4a) and travels along the curtain rail body Runner (4),
An electrode portion (7a) for supplying power to the pair of power supply members (3),
The first and second curtain rail bodies are disposed, and at least one of the curtain rails further includes a pair of power supply extension members (30) in addition to the pair of power supply members (3). Electric curtain rail. The electric curtain rail according to claim 1,
The first and second curtain rail bodies are arranged in series, and in addition to the pair of feeding members (3), each curtain rail body is further provided with a pair of feeding extension members (30). Electric curtain rail. The electric curtain rail according to claim 1,
One end of each of the pair of power supply extension members (30) in the first curtain rail main body is a second pair of electrodes of the electrode portion (7a) inserted into the first curtain rail main body. Electrically connected to each of (7a8),
The other end of the first curtain rail body is connected to the second curtain rail body by a connecting member (9),
The other end of each of the pair of power supply extension members (30) of the first curtain rail body is connected to each of the pair of power supply members (3) of the second curtain rail body by the connection member (9). Electric curtain rail characterized by being electrically connected to In the electric curtain rail according to claim 1 or 2,
The electric curtain rail characterized in that the curtain rail body can be cut at an arbitrary position, and the electrode portion (7a) can be attached to and detached from an end portion of the cut curtain rail body. In the electric curtain rail in any one of Claims 1-3,
The curtain rail body has an upper flange (2a) and a lower flange (2c) that are substantially H-shaped in cross-section perpendicular to the longitudinal direction, and the upper flange (2a) and the lower flange (2c). ) Between the web (2b)
The pair of power supply members (3) are disposed on the upper flange (2a) or the lower flange (2c) or the web (2b),
The drive runner (4) is disposed between a pair of drive wheels (4d) traveling on the upper surface of the lower flange (2c) and at least one of the electric motor (4a) and the pair of drive wheels (4d). An electric curtain rail comprising a rotation transmission mechanism (4c) arranged.

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