JP2021038530A - Electrically-driven shielding device - Google Patents

Abstract

To provide an electrically-driven shielding device that suppresses a deterioration of radio sensitivity in a communication module.SOLUTION: According to the present invention, an electrically-driven shielding device is provided which includes a head box, a control board, and a communication module, with the communication module protruding from the control board to cause a radio wave from an antenna part of the communication module to travel in a direction toward an opening surface of the head box.SELECTED DRAWING: Figure 1

Description

The present invention relates to an electric shielding device that electrically opens and closes a shielding material.

In the electric horizontal blind of Patent Document 1, the motor in the head box is controlled by using the operation switch connected by wire.

Japanese Unexamined Patent Publication No. 2016-29262 Japanese Unexamined Patent Publication No. 2005-179994

In order to improve operability, it is desired to adopt a wireless remote controller such as an RF remote controller. In order to realize a wireless remote controller, it is necessary to incorporate a communication module for wireless communication in the headbox, but it is not possible to incorporate the communication module in the limited space inside the headbox while suppressing the decrease in radio wave sensitivity. It's not easy.

The present invention has been made in view of such circumstances, and provides an electric shielding device in which a decrease in radio wave sensitivity of a communication module is suppressed.

According to the present invention, the head box, the control board, and the communication module are provided, the communication module is projected from the control board, and the direction in which the radio wave of the antenna portion of the communication module travels is directed to the opening surface of the head box. An electric shielding device is provided that is arranged so as to face.

In the configuration of the present invention, since the radio wave of the antenna portion is easily transmitted to the outside of the head box, the decrease in radio wave sensitivity is suppressed.

Hereinafter, various embodiments of the present invention will be illustrated. The various embodiments shown below can be combined with each other.
Preferably, in the electric shielding device according to the above, the communication module is covered so that the antenna portion does not block the progress of radio waves with the control board or a member mounted on the control board with the opening surface. It is an electric shielding device that is configured so as not to be installed and is mounted on the control board and electrically connected.
Preferably, it is the electric shielding device according to the above, wherein the head box is made of metal and the opening surface is formed over the entire length in the longitudinal direction.
Preferably, the electric shielding device according to the above is the electric shielding device in which the communication module is provided with an electrical contact at one end of the control board and is arranged at a position adjacent to the electric shielding device.
Preferably, the electric shielding device according to the above, wherein the antenna portion of the communication module is flat, and the flat antenna portion is arranged so as to be parallel to the opening surface. is there.
Preferably, in the electric shielding device according to the above, the opening surface is provided on the upper surface of the head box, the control board and the antenna portion are arranged on the bottom surface of the head box, and the antenna portion is. An electric shielding device that is directed to the upper surface of the headbox.

According to another aspect of the present invention, the head box, the motor, the control board, the drive shaft, the cover, and the protective sheet are provided, the control board controls the rotation of the motor, and the drive shaft The cover rotates with the rotation of the motor, the cover covers at least a part of the upper surface opening of the head box, and the protective sheet is provided between the motor and the control board of the cover and the drive shaft. An electric shielding device is provided in which a cable arranged between the motor and the control board is arranged so as to pass between the cover and the protective sheet.
Preferably, the electric shielding device according to the above is provided with a rotating member that rotates with the rotation of the drive shaft and a support member that rotatably supports the rotating member, and the rotating member and the support member include the rotating member. The protective sheet is an electric shielding device arranged between the motor and the control board so as to cover the support member.

According to another aspect of the present invention, a head box having an upper surface opening, a cover that closes at least a part of the upper surface opening, a power supply board arranged in the head box, and one end connected to the power supply board. The cover is provided with a notch at the longitudinal end of the cover, and the power cord is provided with an electric shielding device that is led out of the headbox through the notch.
Preferably, it is the electric cloaking device according to the above, wherein the power cord is controllably fixed to the inner surface of the head box.
Preferably, it is the electric shielding device described above, and the power cord is an AC power cord, which is an electric shielding device.

It is a perspective view of the electric horizontal blind 1 of 1st Embodiment of this invention. FIG. 5 is a perspective view of the head box 2 and its internal structure in a state where the side cap 2s and the cover 2c are removed from the state of FIG. 1 and the front wall 2f of the head box 2 is removed. FIG. 3A is an enlarged view of a portion corresponding to the region A of FIG. 2 with the side cap 2s and the cover 2c attached, and FIG. 3B is an enlarged view of the region A of FIG. 4A is an enlarged view of the area B of FIG. 2, and FIG. 4B is a view of the state in which the cables 7a and 10a and the protective sheet 18 are removed from FIG. 4A. FIG. 5A is an enlarged view of the control board 16 and the encoder unit 20 in FIG. 2, and FIG. 5B is a view of a state in which the case 20a is removed from FIG. 5A. 6A to 6B show a cross section perpendicular to the longitudinal direction of the headbox 2 from left to right, passing through points A and B in FIG. 5A with the control board 16 mounted on the headbox 2, respectively. It is a cross-sectional view seen toward. It is an enlarged view of the structure in the vicinity of the motors 7 and 10 and the vibration isolator 19 in FIG. FIG. 7 is an exploded perspective view of FIG. 7. It is an exploded perspective view of the connector 7d. It is sectional drawing of the connector 7d. FIG. 11 shows a configuration in the vicinity of the control board 16 of the second embodiment, and FIGS. 11A and 11B are perspective views viewed from different angles. A state in which the control board 16 of the second embodiment and the members mounted on the control board 16 are mounted on the head box 2 is shown. The configuration in the vicinity of the control board 16 of the third embodiment is shown.

Hereinafter, various embodiments of the present invention will be described with reference to the drawings. The various embodiments shown below can be combined with each other.

1. 1. First Embodiment An electric horizontal blind (an example of an "electric shielding device") 1 of the first embodiment of the present invention will be described.

1-1. Overall Configuration As shown in FIGS. 1 to 4, the electric horizontal blind 1 includes a head box 2, a ladder cord 3, an elevating cord 4, a slat group (an example of a “shielding material”) 5, and a bottom rail 6. Be prepared. The ladder cord 3 and the elevating cord 4 are suspended from the head box 2. The electric horizontal blind 1 can be mounted on a window frame or the like via a mounting bracket 15.

The slat group 5 and the bottom rail 6 are supported by a ladder cord 3. The ladder cord 3 is configured by providing a plurality of stages of weft threads between a pair of warp threads. The slat group 5 is composed of a plurality of stages of slat 5a.

The bottom rail 6 is arranged below the slat group 5. The lower end of the ladder cord 3 and the lower end of the elevating cord 4 are connected to the bottom rail 6. The bottom rail 6 can be raised and lowered by the lifting cord 4, and the slat group 5 moves up and down as the bottom rail 6 moves up and down.

As shown in FIGS. 2 to 4, in the head box 2, an elevating motor (an example of a “motor”) 7, an elevating shaft (an example of a “drive shaft”) 8, and a take-up cylinder (“rotating member”” are included. Example) 9, a tilt motor (an example of a "motor") 10, a tilt shaft (an example of a "drive shaft") 11, a tilter drum (an example of a "rotating member") 12, a support member 13, and an encoder unit. 20, a control board 16, and a power supply board 17 are provided. The output shafts of the motors 7 and 10 are connected to the elevating shaft 8 and the tilt shaft 11 via the couplers 7d and 10d. The motors 7 and 10 are fixed to the head box 2 by the vibration isolator 19.

The number of take-up cylinders 9 is the same as that of the elevating cord 4. The number of tilter drums 12 is the same as that of the ladder code 3. The take-up cylinder 9 and the tilter drum 12 are rotatably supported by the support member 13.

The elevating shaft 8 rotates with the rotation of the elevating motor 7, and the take-up cylinder 9 rotates with the rotation of the elevating shaft 8. The upper end of the elevating cord 4 is connected to the take-up cylinder 9, and the elevating cord 4 is wound up or rewound on the take-up cylinder 9 as the take-up cylinder 9 rotates, so that the bottom rail 6 moves up and down. ..

The tilt shaft 11 rotates with the rotation of the tilt motor 10, and the tilter drum 12 rotates with the rotation of the tilt shaft 11. In the ladder cord 3, the upper ends of the pair of warp threads are connected to the tilter drum 12. As the tilter drum 12 rotates, the ladder cord 3 also rotates, and the inclination angle of the slat group 5 changes.

As shown in FIG. 3, the head box 2 includes a bottom wall 2b, a front wall 2f, and a rear wall 2r. The front wall 2f and the rear wall 2r are provided so as to rise from the front edge and the rear edge of the bottom wall 2b, respectively. The openings at both ends of the head box 2 are closed by the side caps 2s. At least a part of the opening surface 2d on the upper surface of the head box 2 is closed by the cover 2c. The opening surface 2d is formed over the entire length of the head box 2 in the longitudinal direction.

As shown in FIG. 3B, the power supply board 17 is fixed to the rear wall 2r by the board fixture 17c. One end of the AC power cord 17a is connected to the power supply board 17. An outlet plug 17b is provided at the other end of the AC power cord 17a. By inserting the outlet plug 17b into an outlet, AC power can be supplied to the power supply board 17. The power supply board 17 has a function of converting AC power into DC power, and DC power is supplied to the control board 16 via a cable (not shown). The AC power cord 17a is controllably fixed to the inner surface of the head box 2 by a cord fixture 17d. This prevents the AC power cord 17a from coming off the power supply board 17 when the AC power cord 17a is pulled. Further, the AC power cord 17a is led out to the outside of the head box 2 through the opening on the upper surface of the head box 2, and more specifically, is led out to the outside of the head box 2 through the notch 2c1 provided in the cover 2c. In such a configuration, since it is not necessary to pass the AC power cord 17a through the hole, workability is good, and since it is not necessary to provide an opening in the side cap 2s, the design from the side surface is excellent. In the present embodiment, the notch 2c1 is provided at the longitudinal end of the cover 2c, but may be provided at the front or trailing edge of the cover 2c in the vicinity of the longitudinal end of the cover 2c.

A program necessary for controlling the motors 7, 10 and the like is recorded on the control board 16, and the electric horizontal blind 1 operates according to this program. As shown in FIG. 4A, the motors 7 and 10 are connected to the control board 16 via cables 7a and 10a, respectively, and power can be supplied and controlled through the cables 7a and 10a, respectively. The ends of the cables 7a and 10a on the control board 16 side are connected to the control board 16 via the connectors 7b and 10b. The ends of the cables 7a and 10a on the motor 7 and 10 sides are connected to the motor terminals 7c and 10c. As shown in FIG. 4B, the encoder unit 20, the take-up cylinder 9, the support member 13, the vibration isolator 19, and the motors 7 and 10 exist between the connectors 7b and 10b and the motor terminals 7c and 10c. The take-up cylinder 9 and the support member 13 are arranged between the motors 7 and 10 and the control board 16. When the cables 7a and 10a are wired along the bottom wall 2b, the cables 7a and 10a are entangled, the cables 7a and 10a are connected incorrectly, and the cables 7a and 10a are deteriorated by the heat of the motors 7 and 10. There is a problem that there is a risk of doing so. Therefore, in the present embodiment, the protective sheet 18 is arranged between the cover 2c and the elevating shaft 8 between the motors 7 and 10 and the control board 16, and the cables 7a and 10a pass between the cover 2c and the protective sheet 18. It is wired like this. With such a configuration, the above-mentioned problems are solved. In one example, the protective sheet 18 is arranged so as to cover at least one of the encoder unit 20, the take-up cylinder 9, the support member 13, and the vibration isolator 19.

As shown in FIG. 5, a bracket 16a and an encoder unit 20 are mounted in the vicinity of one end and the other end of the control board 16 in the longitudinal direction. As shown in FIG. 6A, the bracket 16a includes a groove-shaped engaging portion 16a3, and the bracket 16a is mounted on the control board 16 by engaging the edge of the control board 16 with the engaging portion 16a3. As shown in FIG. 6B, the encoder unit 20 includes an engaging portion 20f composed of a protrusion 20d protruding downward and a claw portion 20e, and the edge of the control board 16 is engaged with the engaging portion 20f. The encoder unit 20 is mounted on the control board 16. The control board 16 includes a positioning portion 16f, and the claw portion 20e is fitted to the positioning portion 16f.

The bracket 16a includes first and second arms 16a1, 16a2. The front wall 2f and the rear wall 2r of the head box 2 are provided with rails 2f1, 2r1 extending in the longitudinal direction, respectively. The bracket 16a is inserted into the head box 2 from the end of the head box 2 and is configured to be slidable to a desired position along the rails 2f1, 2r1. The bracket 16a slides so that the upper surfaces of the arms 16a1 and 16a2 are along the rails 2f1 and 2r1. The arm 16a2 is provided with a protrusion 16a4 that projects toward the rear wall (an example of a side wall) 2r of the headbox 2. The bracket 16a is positioned in the longitudinal direction of the head box 2 by inserting the protrusion 16a4 into a hole (not shown) provided in the rear wall 2r.

The encoder unit 20 is inserted into the head box 2 from the end of the head box 2 and is configured to be slidable to a desired position along the rails 2f1, 2r1. The encoder unit 20 slides so that the upper surface of the encoder unit 20 is along the lower surface of the rails 2f1, 2r1. The encoder unit 20 is provided with a protrusion 20g that projects toward the rear wall (an example of a side wall) 2r of the head box 2. The encoder unit 20 is stably supported by the protrusion 20g coming into contact with the rear wall 2r.

The control board 16 on which the bracket 16a and the encoder unit 20 are mounted can be engaged with the head box 2 by pushing it from the opening surface 2d on the upper surface of the head box 2 toward the bottom surface, or the opening surface on the upper surface of the head box 2. 2d may be accommodated in the head box while being spread in the front-rear direction with a tool.

In this way, the control board 16 is mounted on the bottom surface of the head box 2 by the bracket 16a and the encoder unit 20.

As shown in FIG. 5, the encoder unit 20 includes a case 20a, a cover 20b, and a plurality of (first and second) encoders 8a and 11a. The encoders 8a and 11a can detect the rotation angles of the elevating shaft 8 and the tilt shaft 11. The encoders 8a and 11a are housed in a housing composed of a case 20a and a cover 20b. The encoders 8a and 11a are arranged so as to be arranged in parallel in the front-rear direction of the head box 2. According to such a configuration, it is possible to arrange the parts in a space-saving manner. The encoders 8a and 11a include first and second rotating discs 8a1 and 11a1. The rotating discs 8a1 and 11a1 are rotatably supported. The plurality of encoders 8a and 11a include a plurality of (first and second) optical sensors 8a2 and 11a2. The first and second optical sensors may be arranged in the housing or may be arranged on the control board 16. The plurality of optical sensors 8a2 and 11a2 are electrically connected to the control board 16, and the electric signals from the plurality of optical sensors 8a2 and 11a2 are individually transmitted to the CPU provided on the control board 16.

As shown in FIG. 5, the control board 16 is provided with a notch 16b, and the encoder unit 20 controls so that the leg portion 20c protruding toward the bottom wall 2b is arranged in the notch 16b. It is mounted on the substrate 16. The notch 16b has a depth such that a part of the control board 16 becomes a protruding portion 16c protruding outward in the longitudinal direction of the control board 16 from the encoder unit 20, and the communication module 16d is arranged in the protruding portion 16c. ing. The communication module 16d has a function of exchanging control signals with and from the wireless remote controller used for operating the electric horizontal blind 1. By arranging the communication module 16d at such a position, the reception sensitivity of the control signal is enhanced. As shown in FIG. 6, the communication module 16d projects from the control board 16 toward the opening surface 2d of the head box 2. An antenna portion (not shown) is provided on the upper surface of the communication module 16d, and the radio wave from the antenna portion travels toward the opening surface 2d. When the head box 2 is made of metal, it is difficult for the head box 2 to pass radio waves, but by directing the direction in which the radio waves of the antenna portion travel toward the opening surface 2d, the attenuation of the radio waves from the antenna portion is suppressed. The opening 2d is covered with the cover 2c, but since the cover 2c is made of resin, the attenuation of radio waves by the cover 2c is small. The opening surface 2d may be provided on the side surface or the bottom surface of the head box 2.

The antenna portion is preferably flat, and the flat antenna portion is preferably arranged so as to be parallel to the opening surface 2d. Further, if the antenna portion is covered with the control board 16 or a member mounted on the control board 16 (eg, the encoder unit 20), the radio wave is attenuated. It is preferable that the member attached to the member does not cover the member so as not to block the progress of the radio wave. Further, it is preferable that the antenna portion is mounted on the control board 16 and electrically connected.

As shown in FIGS. 7 to 8, the vibration isolator 19 has openings 19a and 19b, and the motors 7 and 10 are accommodated by inserting the motors 7 and 10 into the openings 19a and 19b. The anti-vibration material 19 surrounds the motors 7 and 10 from all sides, and a wall 19c is provided between the motors 7 and 10. The anti-vibration material 19 has an uneven structure 19d on at least one outer peripheral surface. The motors 7 and 10 are fixed to the head box 2 in a state of being housed in the vibration isolator 19. The motors 7 and 10 are arranged in parallel in the front-rear direction of the head box 2. The anti-vibration material 19 is preferably made of rubber, and more preferably made of silicone rubber. The anti-vibration material 19 has the largest wall thickness on the surface having the largest contact surface with the head box 2. In the present embodiment, since the anti-vibration material 19 has the largest contact surface with the bottom surface of the head box 2, the wall thickness of the surface of the anti-vibration material 19 that contacts the bottom surface of the head box 2 is the largest.

As shown in FIGS. 9 to 10, the connecting tool 7d includes a first member 7d1, a second member 7d2, and a connecting pin 7d3. The connecting pin 7d3 connects the first member 7d1 and the second member 7d2 so that the first member 7d1 and the second member 7d2 can rotate relative to each other within a predetermined range (60 degrees in this embodiment). It is 10 to 180 degrees, preferably 20 to 120 degrees, and more preferably 30 to 90 degrees.

The first member 7d1 includes an inner connecting portion 7d11 and a shaft insertion cylinder 7d12. The second member 7d2 includes an outer connecting portion 7d21 and a shaft insertion cylinder 7d22. The output shaft 7e of the elevating motor 7 is inserted into the shaft insertion cylinder 7d12, and a fixing screw is screwed into the fixing screw hole 7d13 to fix the output shaft 7e to the shaft insertion cylinder 7d12. The elevating shaft 8 is inserted into the shaft insertion cylinder 7d22, and a fixing screw is screwed into the fixing screw hole 7d23 to fix the elevating shaft 8 to the shaft insertion cylinder 7d22.

An elongated hole 7d14 is provided in the inner connecting portion 7d11. The outer connecting portion 7d21 is provided with a housing recess 7d24 and a pin insertion hole 7d25. The pin insertion hole 7d25 is provided so as to be connected to the accommodating recess 7d24. The inner connecting portion 7d11 and the outer connecting portion 7d21 are connected by inserting the connecting pin 7d3 into the pin insertion hole 7d25 and the elongated hole 7d14 with the inner connecting portion 7d11 housed in the accommodating recess 7d24. The connecting pin 7d3 can move in the elongated hole 7d14, and the inner connecting portion 7d11 has a range in which the connecting pin 7d3 can move in the elongated hole 7d14 with respect to the outer connecting portion 7d21 (60 degrees in this embodiment). ) Is relatively rotatable. According to such a configuration, the vibration of the motor 7 is not easily transmitted to the elevating shaft 8.

An obstacle detection / stopping device having a clutch having the same configuration as that of Patent Document 2 is incorporated in the take-up cylinder 9, and the obstacle detection / stopping device malfunctions due to the vibration of the motor 7, causing the elevating shaft 8 to rotate. There is a risk that it will stop unintentionally. However, in the present embodiment, since the output shaft 7e of the motor 7 is connected to the elevating shaft 8 via the connector 7d having the above configuration, malfunction due to vibration of the motor 7 is suppressed.

2. Second Embodiment The second embodiment of the present invention will be described with reference to FIG. This embodiment is similar to the first embodiment, and the main difference is the difference in the configuration of the communication module 16d. Hereinafter, the differences will be mainly described.

In the present embodiment, the communication module 16d is separate from the control board 16. An electrical contact (not shown) is provided at one end of the control board 16, and the communication module 16d is mounted so that the electrical contact provided on the communication module 16d and the electrical contact of the control board 16 come into contact with each other. Signals can be exchanged between the control board 16 and the communication module 16d. The electrical contacts of the control board 16 are provided on the lower surface of the control board 16, and the communication module 16d is mounted on the lower surface of the control board 16. Further, since the spacer 16d1 is provided between the communication module 16d and the control board 16, the communication module 16d is provided at a position protruding from the lower surface of the control board 16. Therefore, the communication module 16d is less susceptible to noise from the control board 16.

The communication module 16d has an antenna portion 16d2, and the antenna portion 16d2 projects in the longitudinal direction from the control board 16 at a notch 16b provided at one end of the control board 16. Therefore, the antenna portion 16d2 is not covered with the control board 16 and the members mounted on the control board 16, and the attenuation of radio waves is suppressed. Further, as shown in FIG. 12, the point that the radio wave of the antenna portion 16d2 travels is directed to the opening surface 2d of the head box 2 is the same as that of the first embodiment.

3. 3. Third Embodiment The third embodiment of the present invention will be described with reference to FIG. This embodiment is similar to the second embodiment, and the main difference is the difference in the configurations of the communication module 16d and the control board 16. Hereinafter, the differences will be mainly described.

In the present embodiment, the antenna portion 16d2 of the communication module 16d is provided at a position protruding below the control board 16, but does not protrude in the longitudinal direction of the control board 16. Since the control board 16 is provided with the opening 16e so that the antenna portion 16d2 is not covered by the opening 16e, the attenuation of the radio wave is suppressed as in the second embodiment.

4. Other Embodiments The present invention can also be implemented in the following embodiments.
-The configuration of the above embodiment can be applied to any electric shielding device (for example, electric pleated screen, electric roman shade) other than the electric horizontal blind.
-In the above embodiment, the two motors are an elevating motor and a tilt motor, but even if the two elevating motors are provided in an electric shielding device in which two shielding materials are arranged side by side in the front-rear direction or the up-down direction. Good. Similarly, in the above embodiment, the two axes are an elevating axis and a tilt axis, but may be two elevating axes.
The connector 7d can be used to connect any two axes.
-In the above embodiment, the encoders 8a and 11a are housed in one housing, but may be housed in separate housings.
-The encoders 8a and 11a may be arranged so as not to be arranged in parallel in the front-rear direction.
-The electric shielding device of the above embodiment is excellent in operability because the RF remote controller and the infrared remote controller can be operated by both remote controllers. -When a plurality of electric shielding devices of the above embodiment are installed, the plurality of electric shielding devices can be operated at the same timing by broadcast communication from the central control device.

1: Electric horizontal blind 2: Head box 2b: Bottom wall 2c: Cover 2c1: Notch 2d: Opening surface 2f: Front wall 2f1: Rail 2r: Rear wall 2r1: Rail 2s: Side cap 3: Ladder code 4: Lifting cord 5: Slat group 5a: Slat 6: Bottom rail 7: Elevating motor 7a: Cable 7b: Connector 7c: Motor terminal 7d: Connector 7d1: First member 7d11: Inner connecting part 7d12: Shaft insertion cylinder 7d13: Fixing screw hole 7d14 : Long hole 7d2: Second member 7d21: Outer connecting portion 7d22: Shaft insertion cylinder 7d23: Fixing screw hole 7d24: Accommodating recess 7d25: Pin insertion hole 7d3: Connecting pin 7e: Output shaft 8: Elevating shaft 8a: Encoder 8a1: 1-rotating disk 8a2: 1st optical sensor 9: Winding cylinder 10: Tilt motor 10a: Cable 10b: Connector 10c: Motor terminal 10d: Connector 11: Tilt shaft 11a: Encoder 11a1: 2nd rotating disk 11a2: 2nd optical Sensor 12: Connector drum 13: Support member 15: Mounting bracket 16: Control board 16a: Bracket 16a1: First arm 16a2: Second arm 16a3: Engagement part 16a4: Protrusion 16b: Notch 16c: Protrusion part 16d: Communication module 16d1 : Spacer 16d2: Antenna 16e: Opening 17: Power supply board 17a: AC power cord 17b: Outlet plug 17c: Board fixture 17d: Cord fixture 18: Protective sheet 19: Motor bracket 19a: Opening 19b: Opening 20 : Encoder unit 20a: Case 20b: Cover 20c: Leg 20d: Projection 20e: Engagement claw 20f: Engagement part 20g: Projection

Claims (6)

Equipped with a head box, control board, and communication module,
An electric shielding device that projects the communication module from the control board and arranges the direction in which radio waves of the antenna portion of the communication module travel toward the opening surface of the head box. The electric shielding device according to claim 1.
The communication module is configured such that the antenna portion is not covered with the control board or a member mounted on the control board with the opening surface so as not to block the progress of radio waves, and is mounted on the control board for electricity. An electric shielding device that is connected to the antenna. The electric shielding device according to claim 1 or 2.
An electric shielding device in which the head box is made of metal and the opening surface is formed over the entire length in the longitudinal direction. The electric shielding device according to any one of claims 1 to 3.
The communication module is an electric shielding device in which an electric contact is provided at one end of the control board and is arranged at an adjacent position. The electric shielding device according to claim 4.
An electric shielding device in which the antenna portion of the communication module is flat, and the flat antenna portion is arranged so as to be parallel to the opening surface. The electric shielding device according to any one of claims 1 to 5.
The opening surface is provided on the upper surface of the head box.
The control board and the antenna portion are arranged on the bottom surface of the head box.
The antenna portion is an electric shielding device directed to the upper surface of the head box.