JP2021156009A - Stand device and belt partition - Google Patents

Abstract

To provide a stand device and a belt partition that can suppress spread of infectious diseases and also be used as lighting fixture.SOLUTION: A stand device has a pedestal part 2 and a cylindrical strut part 3 fixed to the pedestal part 2. The cylindrical strut part 3 has a cylindrical body 4, a light emitting part 10 housed inside the cylindrical body 4, and an air flow generating part that generates an air flow inside the cylindrical body 4. The light emitting part 10 has an ultraviolet light generating part formed by using an ultraviolet LED module.SELECTED DRAWING: Figure 1

Description

The present invention relates to a partition stand used when a space is partitioned, a stand device used as a floor-standing lighting fixture, and a belt partition having a belt winding portion or a belt locking portion.

Conventionally, a partition stand is known as a member or device for partitioning a space by using a rope or a belt. In the partition stand, when the support (pole) and a member such as a rope that divides the space are separate members (see, for example, Patent Document 1), the support (pole) and the belt that divides the space, etc. It is known that the member is integrated (see, for example, Patent Document 2 and Patent Document 3).

Patent Document 1 discloses a partition stand having a structure in which a hook is formed on an upper end of a support column and a ring at a rope end is hooked on or removed from the hook. Further, Patent Document 2 has a case in which a base, a pole, and a belt to be placed on the floor are wound, the case is fixed to the upper part of the pole, and the belt is pulled out from the case or the belt is wound around the case. A partition stand of a structure to be taken (or a structure having a belt locking portion) (a type of partition stand in which a belt is used as a member for partitioning a space is also referred to as a belt partition) is disclosed. Patent Document 3 discloses a partition stand in which Paul has a display means and the display contents can be changed by the display means.

Japanese Unexamined Patent Publication No. 2013-189746 Japanese Patent No. 5923651 JP-A-2018-165864

The partition stand described above is used as a member or device for partitioning a space. Partition stands are placed in places where a large number of people gather, such as airports, concert halls, hotels, stadiums, commercial facilities, theme parks, terminal stations, and ticket offices, and are used when a large number of people gather. Will be done.

The place where the partition stand is used may be outdoors, but it is often indoors. Then, when the partition stand is used, it is conceivable that a large number of people are gathering around the partition stand indoors and the ventilation is not sufficient. Therefore, some infectious disease may spread among the people gathering around the partition stand.

However, conventional partition stands have not considered controlling the spread of infectious diseases.

The partition stand is also used outdoors. Then, it is possible that a large number of people are gathering around the partition stand during the dark hours. Therefore, it is desirable that the partition stand can secure light around the gathered people.

As described above, it is desirable that the partition stand mainly suppresses the spread of infectious diseases in preparation for indoor use and can be used as a lighting fixture in preparation for outdoor use. However, in the past, there was no partition stand in which both were realized.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a stand device and a belt partition that can suppress the spread of infectious diseases and can also be used as lighting equipment. do.

In order to solve the above problems, the present invention has a pedestal portion and a tubular strut portion fixed to the pedestal portion, and the tubular strut portion is inside the tubular body and the tubular body. The light emitting unit includes a light emitting unit that is accommodated and an air flow generating unit that generates an air flow inside the cylindrical body, and the light emitting unit provides a stand device having an ultraviolet light generating unit that generates ultraviolet rays.

In the case of the stand device, the tubular body has an intake portion for taking in outside air and an exhaust portion for discharging the air taken in from the intake portion, and the exhaust portion is from the pedestal portion rather than the intake portion. It is preferable that they are arranged at distant positions.

Further, the ultraviolet light generating portion is formed by using an ultraviolet LED module in which a plurality of ultraviolet light emitting diodes that generate ultraviolet rays are arranged, and the ultraviolet LED module is arranged inside the tubular body along the axial direction of the tubular body. It is preferable that it is.

Further, it is preferable that the tubular body has an ultraviolet shielding portion that blocks or absorbs ultraviolet rays and transmits visible light on the front side of the light source.

In addition, the tubular body shall be formed in a rectangular shape in a plan view using resin, and an ultraviolet shielding portion that blocks or absorbs ultraviolet rays and transmits visible light shall be formed on the front side of the light source. You can also.

The stand device further has a storage battery charged by a commercial power source, the storage battery is housed inside a cylindrical body, and the storage battery is connected to a light emitting unit and an air flow generating unit. You can also do it.

Further, it further has a guide member that is closely housed inside the tubular body, and the guide member has a shape in which an axial airflow along the axial direction of the tubular body is formed by an airflow generating portion. However, it is preferable that the light emitting portion and the airflow generating portion are fixed to the portions along the axial airflow of the guide member.

The present invention has a stand device, a belt winding portion for winding the belt, or a belt locking portion for locking the belt, and the belt winding portion or the belt locking portion is used as the stand device. A fixed belt partition, the stand device has a pedestal portion and a tubular strut portion fixed to the pedestal portion, and the tubular strut portion is a tubular body and the tubular body. The light emitting unit has a light emitting unit housed inside and an air flow generating unit that generates an air flow inside the tubular body thereof, and the light emitting unit provides a belt partition having an ultraviolet ray generating unit that generates ultraviolet rays.

Further, in the case of the belt partition, the tubular body has an intake portion for taking in outside air and an exhaust portion for discharging the air taken in from the intake portion, and the exhaust portion is a pedestal rather than the intake portion. It is preferable that it is arranged at a position away from the portion.

Further, the ultraviolet light generating portion is formed by using an ultraviolet LED module in which a plurality of ultraviolet light emitting diodes that generate ultraviolet rays are arranged, and the ultraviolet LED module is arranged inside the tubular body along the axial direction of the tubular body. It is preferable that it is.

As described in detail above, according to the present invention, it is possible to obtain a stand device and a belt partition that can suppress the spread of an infectious disease and can also be used as a lighting fixture.

It is a side view which showed the schematic structure of the belt partition and the stand device which concerns on embodiment of this invention. It is a perspective view which showed the schematic structure of another belt partition which concerns on embodiment of this invention. It is a top view of the tubular support part of the stand device which constitutes the belt partition of FIG. 1 from the upper side. It is a perspective view which shows the guide member, the light emitting part fixed to the guide member, and the airflow generation part. It is a front view which partially omitted which shows the main part of the tubular support part. It is a top view of the ultraviolet LED module. It is a perspective view which shows an example of the airflow generation part. It is a partially omitted perspective view which shows an example of a cylindrical strut part, an intake part, and an airflow generation part. It is a block diagram which shows typically the circuit structure of the belt partition. It is a perspective view which shows the partition unit including the belt partition of FIG. 1 and the belt partition of FIG. It is a block diagram which shows the circuit structure of the airflow generation part which concerns on the modification, and the battery and a control unit. It is a perspective view which shows the operation content of the airflow generation part which concerns on a modification. It is a perspective view which showed the schematic structure of the belt partition and the stand device which concerns on a modification. It is a perspective view which showed the schematic structure of the stand device which concerns on a modification. It is a perspective view which showed the schematic structure of the stand device which concerns on another modification.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same reference numerals are used for the same elements, and duplicate description will be omitted.

The belt partition 100 according to the embodiment of the present invention will be described with reference to FIGS. 1 to 9. FIG. 1 is a side view showing a schematic configuration of a belt partition 100 and a stand device 1 according to an embodiment of the present invention. FIG. 2 is a perspective view showing a schematic configuration of the belt partition 110 according to the embodiment of the present invention. FIG. 3 is a plan view of the cylindrical support portion 3 of the stand device 1 constituting the belt partition 100 as viewed from above, and FIG. 4 shows the guide member 30, the light emitting portion 10 fixed to the guide member 30, and the airflow generating portion 20. It is a perspective view which shows. FIG. 5 is a partially omitted front view showing a main part of the cylindrical support portion 3. FIG. 6 is a plan view of the ultraviolet LED module 10A, and FIG. 7 is a perspective view of the airflow generating unit 20. FIG. 8 is a partially omitted perspective view showing the cylindrical strut portion 3, the intake portion 5, and the airflow generating portion 20. FIG. 9 is a block diagram schematically showing the circuit configuration of the belt partition 100.

(Structure of belt partitions 100 and 110)
As shown in FIG. 1, the belt partition 100 according to the embodiment of the present invention has a stand device 1 and a belt winding unit 70. The belt partition 100 has a structure in which the belt winding portion 70 is fixed to the stand device 1. Further, as shown in FIG. 2, the belt partition 110 according to the embodiment of the present invention has a stand device 1 and a belt locking portion 90. The belt partition 110 has a structure in which the belt locking portion 90 is fixed to the stand device 1.

In the belt partition 100, the belt winding unit 70 is fixed to the stand device 1, but the belt winding unit 70 may be detachable from the stand device 1 (not shown). Further, in the belt partition 110, the belt locking portion 90 is fixed to the stand device 1, but the belt locking portion 90 may be detachable from the stand device 1 (not shown).

(Structure of stand device 1)
The stand device 1 has a pedestal portion 2 and a cylindrical strut portion 3 fixed to the pedestal portion 2.

As shown in FIG. 2, the pedestal portion 2 includes a substantially disk-shaped plate-shaped portion 2a, a receiving cylinder portion 2b fixed to the center of the front side of the plate-shaped portion 2a in a plan view, a power supply device 2c, and a power supply cord. It has 2d and a power plug 2e.

The receiving cylinder portion 2b is a cylindrical member and has a size in which the tubular strut portion 3 can be accommodated. The power supply device 2c includes a power supply circuit, a constant current circuit, and the like that generate a direct current used in the infrared LED module 10A described later from a commercial power supply. The power supply device 2c is housed inside the receiving tube portion 2b. The power cord 2d is connected to the power supply device 2c and is led out to the outside of the receiving cylinder portion 2b. The power plug 2e is connected to the power cord 2d and is used by inserting and removing it from a commercial power outlet (not shown).

As shown in FIG. 1, the tubular support portion 3 has a tubular body 4, a light emitting portion 10 housed inside the tubular body 4, and an air flow generation that generates an air flow inside the tubular body 4. It has a unit 20 and a battery 8. The lower end portion of the tubular body 4 is fixed to the receiving cylinder portion 2b, and the upper end portion is fixed to the belt winding portion 70.

The tubular body 4 is a cylindrical member made of resin or metal. Considering the case where the stand device 1 is used as a lighting device, the tubular body 4 is preferably formed by using a resin material such as transparent acrylic or impact resistant polycarbonate.

The tubular body 4 has an intake portion 5, an exhaust portion 6, and an ultraviolet shielding portion 7. The intake portion 5 is formed in a mesh shape so as to take in outside air, and a filter 5b (see FIG. 8) is mounted inside. The exhaust unit 6 is a portion where the air taken in from the intake unit 5 is discharged, and is formed in the same mesh shape as the intake unit 5. The exhaust portion 6 is arranged at a position farther from the pedestal portion 2 than the intake portion 5.

The ultraviolet shielding portion 7 is formed on a side surface portion of the tubular body 4 corresponding to the front side of the light emitting portion 10. A resin-made ultraviolet cut film or an ultraviolet filter is attached to a side surface portion of the tubular body 4 corresponding to the front side of the light emitting portion 10, so that the ultraviolet shielding portion 7 can be formed. For example, when a film having a predetermined thickness (for example, 4 mm or more) is formed by using a fluororesin that transmits ultraviolet rays and visible rays, the ultraviolet transmittance of the film is significantly suppressed. Further, when the film thickness is larger (for example, 5 mm or more), the ultraviolet rays are substantially absorbed by the film. Therefore, when a film having a predetermined thickness (for example, 4 mm or more) is formed by using a fluororesin that transmits ultraviolet rays and visible rays, the film blocks or absorbs ultraviolet rays. Therefore, the film is fixed to the tubular body 4 by sticking or the like, so that the ultraviolet shielding portion 7 is formed.

The light emitting unit 10 has an ultraviolet light generating unit that generates ultraviolet rays. In the present embodiment, the ultraviolet ray generating portion is formed by using the ultraviolet LED module (hereinafter, also referred to as “UV-LED module”) 10A. The light emitting unit 10 has a UV-LED module 10A, a wiring cord for connecting the UV-LED module 10A to the power supply device 2c, and the like.

As shown in FIG. 6, the UV-LED module 10A has a rectangular substrate 11 and an ultraviolet LED chip 12, and a plurality of ultraviolet LED chips 12 are arranged on the substrate 11. An input terminal portion 13 and an output terminal portion 14 are arranged on the substrate 11 together with the ultraviolet LED chip 12. Each ultraviolet LED chip 12 has an ultraviolet light emitting diode (UV-LED) 15 that generates ultraviolet rays.

Then, as shown in FIG. 5, two UV-LED modules 10A are arranged side by side inside the tubular body 4 so as not to overlap with each other along the axial direction of the tubular body 4. The input terminal portion 13 and the output terminal portion 14 of each UV-LED module 10A are connected to the power supply device 2c using a wiring cord.

The airflow generation unit 20 is a member that generates an airflow inside the tubular body 4. As shown in FIGS. 4, 7, and 8, the belt partitions 100 and 110 and the stand device 1 according to the present embodiment include the sirocco fan unit 20A as the airflow generating unit 20.

The sirocco fan unit 20A has a sirocco fan 21 and a case 22 in which the sirocco fan 21 is rotatably housed. The case 22 has an intake hole 22a and an exhaust hole 22b. When the sirocco fan 21 rotates in the direction of the arrow in FIG. 7, the intake air 21a is sucked from the intake hole 22a, and the exhaust 21b is discharged from the exhaust hole 22b.

The sirocco fan unit 20A is arranged on the back side (or the upper side of the intake unit 5) of the intake unit 5 inside the tubular body 4.

The battery 8 is housed on the back side of the intake portion 5 inside the tubular body 4. The battery 8 is a storage battery charged by a commercial power source, and for example, a lithium ion battery is used. As shown in FIG. 9, the battery 8 is connected to the UV-LED module 10A and the sirocco fan unit 20A via the power supply device 2c.

Further, the stand device 1 has a guide member 30. As shown in FIG. 4, the guide member 30 is a member having a substantially U-shaped cross section and is housed closely inside the tubular body 4.

The guide member 30 has a pair of side panels 30a and 30b and a bottom panel 30c, whereby an airflow (axial airflow) af along the axial direction of the tubular body 4 can be formed. The axial airflow af is formed by the operation of the sirocco fan unit 20A.

Further, two UV-LED modules 10A and a sirocco fan unit 20A are fixed to the bottom panel 30c of the guide member 30 along the axial direction of the tubular body 4. The guide member 30, the two UV-LED modules 10A, and the sirocco fan unit 20A are integrally housed inside the tubular body 4. The width of the bottom panel 30c (the distance between the side panels 30a and 30b) is formed to a size corresponding to the width of the UV-LED module 10A.

(Structure of belt winding portion 70 and belt locking portion 90)
As shown in FIG. 1, the belt winding portion 70 includes a cylindrical case 71, a cover 72, belt winding pins 73 and 73, belts 74 and 74, a winding mounting force member 75, and a guide pin 76. It has 76 and.

The tubular case 71 is a member formed in a substantially cylindrical shape according to the tubular body 4, and is fixed to the upper end portion of the tubular body 4. The cover 72 is fixed to the upper end of the tubular case 71. The belt take-up pins 73 and 73 are housed inside the tubular case 71 in a state of being rotatably supported, and one ends of the belts 74 and 74 are fixed, respectively. The winding mounting force member 75 has a spring member or the like (not shown), is urged according to the pull-out length of the belts 74, 74, and operates so as to pull in the belts 74, 74. The guide pins 76 and 76 are fixed to the side surface portion of the tubular case 71 and are members for guiding the pulling out and winding of the belts 74 and 74.

As shown in FIG. 2, the belt locking portion 90 has a cylindrical case 71 and a cover 72 similar to the belt winding portion 70, and further has belt receiving grooves 77, 77, 77, 77. The belt receiving groove 77 is a groove-shaped member formed at the tip of the belt 74 according to a hooking member (not shown). The belt receiving grooves 77, 77, 77, and 77 are fixed at positions where they are lined up in a cross shape on the side surface of the tubular case 71 (positions where the covers 72 are lined up in a cross shape when viewed in a plane).

(How to use belt partitions 100 and 110, effects)
The belt partitions 100 and 110 having the above configuration are used, for example, as follows.

As shown in FIG. 10, the belt partitions 100 and 110 are arranged one by one at appropriate intervals. Then, the belt 74 is pulled out from the belt partition 100, and a hooking member (not shown) of the belt 74 is fitted into the belt receiving groove 77 of the belt partition 110. By doing so, the belt 74 is stretched between the belt partition 100 and the belt partition 110, and the partition unit 130 including the belt partitions 100 and 110 is formed. The space is partitioned by the partition unit 130. Also, by arranging a plurality of partition units 130, a large number of people are arranged.

Then, when one or both power plugs 2e of the belt partitions 100 and 110 are plugged into an outlet of a commercial power source (not shown), the battery 8 is charged using the commercial power source. Further, by turning on the power switch (not shown) of the belt partitions 100 and 110, power is supplied from the power supply device 2c to the UV-LED module 10A of the light emitting unit 10 and the sirocco fan unit 20A. Then, in each UV-LED module 10A, the UV-LED 15 lights up. Then, the light emission of UV-LED15 is obtained, and ultraviolet rays are generated. When the power plug 2e is disconnected from a commercial power outlet (not shown), the power charged in the battery 8 is supplied to the UV-LED module 10A and the sirocco fan unit 20A.

On the other hand, the sirocco fan 21 is operated by supplying electric power to the sirocco fan unit 20A. Then, as shown in FIG. 8, the outside air f is taken in from the intake unit 5. After the floating matter such as dust and dirt is removed by the filter 5b, the outside air f becomes the intake air 21a and is sucked into the intake hole 22a of the sirocco fan unit 20A. Then, the blast 21b is discharged from the exhaust hole 22b.

Further, as shown in FIG. 4, an axial airflow af is formed by the blower 21b, and the axial airflow af is sent out toward the exhaust unit 6 while being guided by the guide member 30. Since the two UV-LED modules 10A are fixed to the guide member 30, the axial airflow af passes through the two UV-LED modules 10A before reaching the exhaust unit 6. At that time, the ultraviolet rays generated by the UV-LED 15 are applied to the axial airflow af. As a result, bacteria, viruses, etc. contained in the axial airflow af are sterilized, sterilized, sterilized, etc. by the ultraviolet rays generated by the UV-LED15. Therefore, the clean axial airflow af is discharged from the exhaust unit 6. Since the axial airflow af passes through a groove-shaped route defined by the guide member 30 and the UV-LED module 10A is arranged on the route, the axial airflow af is surely irradiated with ultraviolet rays.

Since the tubular body 4 is formed in a cylindrical shape, when the UV-LED module 10A is fixed inside the tubular body 4, the tubular body 4 and the UV- are between the tubular body 4 and the UV-LED module 10A. Due to the difference in the shape of the LED module 10A, a gap like the mesh portion shown in FIG. 3 is formed. Then, since the gap is on the back side of the UV-LED module 10A, the air passing through the gap is not irradiated with ultraviolet rays. In order to prevent the generation of air that is not irradiated with ultraviolet rays, it is preferable that the guide member 30 is arranged inside the tubular body 4. When the tubular body 4A is formed in a rectangular shape in a plan view as in the belt partition 100A and the stand device 1A described later, it is possible to prevent a gap like the mesh portion shown in FIG. 3 from being formed. In this case, the guide member 30 does not have to be arranged inside the tubular body 4A.

Further, when the UV-LED 15 emits light, light (LED light) is emitted around the belt partitions 100 and 110. The LED light brightens the periphery of the belt partitions 100 and 110.

By the way, since the belt partitions 100 and 110 are used as members for partitioning the space, they are arranged in a place where a large number of people gather and are used when a large number of people are lined up. Then, especially when the belt partitions 100 and 110 are arranged indoors, there is little ventilation, and therefore some infectious disease may spread among the people gathering around the belt partitions 100 and 110.

However, as described above, in the belt partitions 100 and 110, air is sterilized, sterilized, sterilized and the like by irradiation with ultraviolet rays. Therefore, the periphery of the belt partitions 100 and 110 is surrounded by clean air that has been sterilized, sterilized, and sterilized. Therefore, by using the belt partitions 100 and 110, the risk of spreading the infectious disease among the people gathered around the belt partitions 100 and 110 is suppressed.

On the other hand, since the belt partitions 100 and 110 generate ultraviolet rays, the ultraviolet rays may hurt the eyes of people gathered around the belt partitions 100 and 110.

However, in the belt partitions 100 and 110, the ultraviolet shielding portion 7 is arranged on the front side of the UV-LED module 10A. Therefore, the ultraviolet rays generated by the UV-LED module 10A are blocked or absorbed by the ultraviolet shielding portion 7. Therefore, ultraviolet rays are generated from the UV-LED module 10A, and after the axial airflow af is sterilized and sterilized, the outside of the ultraviolet shielding portion 7 is not irradiated. Therefore, there is no risk of the gathered people hurt their eyes.

Moreover, since the tubular body 4 is formed of acrylic or polycarbonate, the tubular body 4 functions as a panel for indirect lighting. Therefore, the LED light emitted by the UV-LED module 10A becomes the light of indirect lighting and spreads around the belt partitions 100 and 110. Therefore, the belt partitions 100 and 110 are used as a lighting fixture that emits a soft light. The belt partitions 100 and 110 have a stand device 1, and the stand device 1 also suppresses the risk of spreading an infectious disease like the belt partitions 100 and 110 and is used as a lighting fixture.

In the belt partitions 100 and 110, the exhaust portion 6 is arranged at a position farther from the pedestal portion 2 than the intake portion 5. Therefore, even if the temperature of the axial airflow af rises due to the irradiation of the LED light emitted by the UV-LED module 10A, the axial airflow af moves toward the exhaust unit 6 and is discharged from the exhaust unit 6.

(Modification example 1)
Next, the airflow generation unit 120 according to the modified example will be described with reference to FIGS. 11 and 12. FIG. 11 is a block diagram showing a circuit configuration of the airflow generation unit 120, the battery 8, and the control unit 8b. FIG. 12 is a perspective view showing the operation contents of the airflow generation unit 120.

The airflow generation unit 120 has a fibrous metal member 121, a deformable member 122, and a wiring cord 123. The fibrous metal member 121 is a member processed into a fibrous form using a Ti—Ni-based shape memory alloy. The fibrous metal member 121 is formed by anisotropic organization so that the characteristics are brought out in a certain predetermined direction. As a result, the shape of the fibrous metal member 121 can be switched between a state in which a current is not flowing and a state in which a current is flowing. When no current is applied, it becomes flexible and curved like nylon fiber. On the other hand, when an electric current is applied, it becomes hard and contracts, so that the whole becomes tense and straight.

A plurality of fibrous metal members 121 of the airflow generating unit 120 are fixed side by side on the deforming member 122. The deformable member 122 is a film or thin plate-like member having a length longer than the length of the fibrous metal member 121 and a size in which a plurality of fibrous metal members 121 are arranged, and is a flexible insulating material (for example, plastic). Etc.).

The airflow generation unit 120 has a configuration in which each fibrous metal member 121 is connected to the battery 8 and the control unit 8b. The control unit 8b has a circuit for switching whether or not power is supplied from the battery 8 (a state in which the current from the battery 8 is flowing or not flowing).

Since the control unit 8b switches between a state in which the current from the battery 8 is flowing and a state in which the current is not flowing, in the airflow generating unit 120, as shown in FIG. 12, the shape of the deforming member 122 is in a flat state and a curved state. It changes with. Therefore, by repeating this change in shape many times, the air above the deforming member 122 can be moved, and as a result, a weak air flow is formed. Therefore, the belt partition and the stand device (not shown) having the airflow generating section 120 instead of the airflow generating section 20 also have the same effects as those of the belt partitions 100, 110 and the stand device 1.

(Modification 2)
Next, with reference to FIG. 13, the belt partition 100A and the stand device 1A according to the modified example will be described. FIG. 13 is a perspective view showing a schematic configuration of the belt partition 100A and the stand device 1A.

The belt partition 100A has a stand device 1A and a belt winding unit 70A. The belt partition 100A has a structure in which the belt winding portion 70A is fixed to the stand device 1A.

The stand device 1A has a pedestal portion 2A and a cylindrical support portion 3A fixed to the pedestal portion 2A. The pedestal portion 2A is a member having a rectangular shape in a plan view, and a cylindrical support portion 3A is fixed to the surface 2B.

The tubular strut portion 3A has a tubular body 4A, a light emitting portion 10 housed inside the tubular body 4A, an air flow generating unit 20, a power supply device 2c, a battery 8, and a solar panel 25. .. The tubular body 4A is formed by using the same resin material as the tubular body 4 such as acrylic and polycarbonate. The tubular body 4 is formed in a rectangular shape in a plan view.

Further, the tubular body 4A has an intake portion 5, an exhaust portion 6 and an ultraviolet shielding portion 7 similar to the tubular body 4 on the side surface on the front side. Further, the solar panel 25 is fixed to another side surface of the tubular body 4A. Further, the battery 8 and the power supply device 2c are housed under the tubular body 4A. A power cord 2d with a power plug 2e is connected to the power supply 2c.

The belt winding portion 70A has a cylindrical case 71A and a cover 72A. Further, the belt winding unit 70A has the same belt winding pins 73 and 73 as the belt winding unit 70, belts 74 and 74, winding mounting force members 75, and guide pins 76 and 76. ..

The tubular case 71A is formed in a rectangular shape in a plan view corresponding to the tubular body 4A. The cover 72A is fixed to the upper end of the cylindrical case 71A.

Like the belt partition 100 and the stand device 1, the belt partition 100A and the stand device 1A having the above-described configuration have a light emitting unit 10 and an air flow generating unit 20, so that the surrounding air is sterilized and sterilized. It can be made into clean air that has been sterilized. Further, the belt partition 100A and the stand device 1A can be used as a lighting device as well as the belt partition 100 and the stand device 1. Since the belt partition 100A and the stand device 1A have a solar panel 25, the solar panel 25 can be used to generate electricity and charge the battery 8.

(Modification example 3)
Next, the stand device 41 according to the modified example will be described with reference to FIG. FIG. 14 is a perspective view showing a schematic configuration of the stand device 41.

Compared with the stand device 1, the stand device 41 has a spherical protrusion 79 fixed to the upper end portion instead of the belt winding portion 70, a pedestal portion 2D instead of the pedestal portion 2, and a cylindrical support. The difference is that the hooks 80 and 80 are fixed to the tubular body 4 of the portion 3. Further, the power supply device 2c is housed inside the tubular body 4.

The stand device 41 does not have a belt take-up portion 70. The stand device 41 has hooks 80, 80. Therefore, as shown in FIG. 14, the ring member 84a of the partition rope 84 is hooked on the hook 80 to be used as a member or device for partitioning the space. The pedestal portion 2D is formed in a circular plate shape.

Since the stand device 41 has the same cylindrical strut portion 3 as the stand device 1, the surrounding air can be sterilized, sterilized, and the like. Therefore, it is possible to suppress the spread of the infectious disease among the people who gather around. Further, since the light emitting portion 10 of the cylindrical strut portion 3 emits light and the light is emitted to the surroundings, it can also be used as a lighting fixture.

(Modification example 4)
Subsequently, with reference to FIG. 15, the stand device 51 according to the modified example will be described. FIG. 15 is a perspective view showing a schematic configuration of the stand device 51.

The stand device 51 has a cylindrical support portion 43 and a pedestal portion 2B. The tubular strut portion 43 differs from the tubular strut portion 3 in that it has a tubular body 42 instead of the tubular body 4. Although the tubular body 42 is formed in a rectangular shape in a plan view, it has an intake portion 5, an exhaust portion 6, and an ultraviolet shielding portion 7 like the tubular body 4. Further, the light emitting units 10 and 10, the air flow generating unit 20, the battery 8 and the power supply device 2c are housed inside the tubular body 42.

The stand device 51 has a cylindrical support portion 43, and has the same light emitting portions 10 and 10 and an air flow generating portion 20 in the cylindrical support portion 43, so that the surrounding air is sterilized and sterilized. Etc. Therefore, it is possible to suppress the spread of the infectious disease among the people who gather around. Further, since the light emitting portion 10 of the cylindrical support portion 43 emits light and the LED light is emitted to the surroundings, the stand device 51 can be used as a lighting fixture. There is no danger that the gathered people will be hurt by the ultraviolet rays.

In the above embodiment, the sirocco fan unit 20A is described as an example of the airflow generation unit 20, but a propeller fan may be used. Further, as a type that does not use a fan, an airflow generating unit 120 having a plurality of fibrous metal members 121 will be described as an example. By increasing the thickness of the fibrous metal member 121 and increasing the wiring density as compared with the case of FIG. 11, a larger air flow is formed. Further, in order to secure the brightness, the UV-LED module 10A may have an LED that generates visible light in addition to the UV-LED15.

By applying the present invention, it is possible to obtain a stand device and a belt partition that can suppress the spread of an infectious disease and can also be used as a lighting fixture. The present invention can be used in the field of stand devices and belt partitions.

1,1A, 41,51 ... Stand device, 2,2A, 2B, 2D ... Pedestal part, 3,43,3A ... Cylindrical strut part, 4,4A, 42 ... Cylindrical body, 5 ... Intake part, 6 ... Exhaust part, 7 ... UV shielding part, 8 ... Battery, 10 ... Light emitting part, 12 ... UV LED chip, 15 ... UV-LED, 10A ... UV-LED module, 20,120 ... Airflow generator, 30 ... Guide member, 70, 70A ... Belt winding part, 90 ... Belt locking part, 100, 110, 100A ... Belt partition.

In order to solve the above problems, the present invention has a pedestal portion and a tubular strut portion fixed to the pedestal portion, and the tubular strut portion is inside the tubular body and the tubular body. It has a light emitting part housed and an airflow generating part that generates an airflow inside the tubular body, the light emitting part has an ultraviolet ray generating part that generates ultraviolet rays, and the ultraviolet ray generating part has a tubular shape. It has a vertically elongated plate-shaped substrate having a width that can be arranged inside the body and a height that is larger than the width, and a plurality of ultraviolet light emitting diodes that generate ultraviolet rays, and the plurality of ultraviolet light emitting diodes are along the width. It is formed by using an ultraviolet LED module arranged in a plurality of rows in a vertical direction and arranged in a plurality of rows in a vertical width direction on a substrate, and has a pair of side panels and a bottom panel. Moreover, the pair of side panels and the bottom panel are plate-shaped members having a length larger than the vertical width of the substrate, respectively, and the distance between the side panels is a vertically long structure having a size corresponding to the horizontal width of the substrate, and the cross section is approximately U. It further has a guide member formed in a character shape, and the guide member is the most from the bottom panel of each of the pair of side panels so that the pair of side panels and the bottom panel are along the axial direction of the tubular body. The corners of the separated end and bottom panel and the pair of side panels are both closely housed inside the tubular body, and the UV generator substrate and airflow generator are fixed to the bottom panel. A stand device that is housed inside a tubular body so as to be surrounded by a pair of side panels, a bottom panel, and a tubular body.

In the case of the stand device, the airflow generated by the airflow generator passes through a vertically long region surrounded by a pair of side panels, a bottom panel and a cylindrical body of the guide member and along the axial direction, and the airflow passes through the vertically long region. It is preferable that the airflow is irradiated with ultraviolet rays generated by a plurality of ultraviolet light emitting diodes when passing through.

Further, it is preferable that the pair of side panels and the bottom panel have a length larger than the vertical width of the substrate and have a length in which the ultraviolet LED module and the air flow generating portion are arranged so as not to overlap in the axial direction. ..

Further, the airflow generating unit is a film or thin plate-like member having a size in which a plurality of fibrous metal members processed into a fibrous shape using a shape memory alloy and the plurality of fibrous metal members are arranged. The airflow generating unit has a deformable member formed by using a flexible insulating material, and a control means for switching between a state in which a current is passed and a state in which a current is not passed through the plurality of fibrous metal members. It is possible to have a structure in which a plurality of fibrous metal members are arranged and fixed on the deformable member, and the deformable member changes between a flat state and a curved state.

Further, the tubular body has an intake portion for taking in outside air and an exhaust portion for discharging the air taken in from the intake portion, and the exhaust portion is located at a position farther from the pedestal portion than the intake portion. It is also possible that an ultraviolet shielding portion that is arranged, blocks or absorbs ultraviolet rays, and transmits visible light is formed between an intake portion and an exhaust portion on the front side of the light emitting portion of the tubular body. can.

Further, the present invention has a pedestal portion and a tubular strut portion fixed to the pedestal portion, and the tubular strut portion is a tubular body and light emitting light housed inside the tubular body. It has a part and an airflow generating part that generates an airflow inside the tubular body, the light emitting part has an ultraviolet ray generating part that generates ultraviolet rays, and the airflow generating part is fibrous using a shape memory alloy. A plurality of fibrous metal members processed into the above, and a film or thin plate-like member having a size in which the plurality of fibrous metal members are arranged, and a deformable member formed by using a flexible insulating material. The airflow generating unit has a control means for switching between a state in which a current is passed through the plurality of fibrous metal members and a state in which no current is passed, and a plurality of fibrous metal members are arranged and fixed on the deformable member. Provided is a stand device having a structure and changing a deformable member into a flat state and a curved state.

The present invention has a stand device, a belt winding portion for winding the belt, or a belt locking portion for locking the belt, and the belt winding portion or the belt locking portion is fixed to the stand device. The stand device has a pedestal portion and a tubular strut portion fixed to the pedestal portion, and the tubular strut portion is a tubular body and the tubular body. It has a light emitting part housed inside the body and an airflow generating part that generates an airflow inside the tubular body, and the light emitting part has an ultraviolet ray generating part that generates ultraviolet rays, and the ultraviolet ray generating part is , A vertically elongated plate-shaped substrate having a width that can be arranged inside a tubular body and a height that is larger than the width, and a plurality of ultraviolet light emitting diodes that generate ultraviolet rays, and the plurality of ultraviolet light emitting diodes A pair of side panels and a bottom panel are formed by using an ultraviolet LED module arranged on a substrate so as to be arranged in a plurality of rows in a direction along a horizontal width and in a plurality of rows in a direction along a vertical width. It has a vertically long structure in which the pair of side panels and the bottom panel each have a length larger than the vertical width of the substrate, and the distance between the side panels has a size corresponding to the horizontal width of the substrate. Further having a guide member having a substantially U-shaped cross section, the guide member has a pair of side panels and a bottom panel along the axial direction of the tubular body, and the bottom surface of each of the pair of side panels. The end part farthest from the panel and the corner part where the bottom panel and the pair of side panels are connected are both housed closely inside the tubular body, and the substrate and airflow generating part of the ultraviolet ray generating part are the bottom panel. Provided is a belt partition that is secured to and enclosed by a pair of side panels, bottom panels and tubulars and housed inside the tubulars.

Further, in the case of the belt partition, the airflow generated by the airflow generator passes through a vertically long region surrounded by a pair of side panels, a bottom panel and a tubular body of the guide member and along the axial direction, and the vertically long region thereof. It is preferable that the airflow is irradiated with ultraviolet rays generated by a plurality of ultraviolet light emitting diodes when the airflow passes through the airflow.

Further, it is preferable that the pair of side panels and the bottom panel have a length larger than the vertical width of the substrate and have a length in which the ultraviolet LED module and the air flow generating portion are arranged so as not to overlap in the axial direction. ..

Further, the airflow generating unit is a film or thin plate-like member having a size in which a plurality of fibrous metal members processed into a fibrous shape using a shape memory alloy and the plurality of fibrous metal members are arranged. The airflow generating unit has a deformable member formed by using a flexible insulating material, and a control means for switching between a state in which a current is passed and a state in which a current is not passed through the plurality of fibrous metal members. It is possible to have a structure in which a plurality of fibrous metal members are arranged and fixed on the deformable member, and the deformable member changes between a flat state and a curved state.

Claims (10)

It has a pedestal portion and a cylindrical strut portion fixed to the pedestal portion.
The tubular strut portion has a tubular body, a light emitting portion housed inside the tubular body, and an air flow generating portion that generates an air flow inside the tubular body.
The light emitting unit is a stand device having an ultraviolet light generating unit that generates ultraviolet rays. The tubular body has an intake portion from which outside air is taken in and an exhaust portion from which air taken in from the intake portion is discharged, and the exhaust portion is located at a position farther from the pedestal portion than the intake portion. The stand device according to claim 1, which is arranged. The ultraviolet light generating portion is formed by using an ultraviolet LED module in which a plurality of ultraviolet light emitting diodes that generate ultraviolet rays are arranged.
The stand device according to claim 1 or 2, wherein the infrared LED module is arranged inside the cylindrical body along the axial direction of the tubular body. The stand device according to any one of claims 1 to 3, wherein the tubular body has an ultraviolet shielding portion that blocks or absorbs ultraviolet rays and transmits visible light on the front side of the light source. The tubular body is formed in a rectangular shape in a plan view using a resin, and an ultraviolet shielding portion that blocks or absorbs ultraviolet rays and transmits visible light is formed on the front side of the light source. The stand device according to any one of 3. It also has a storage battery that is charged by commercial power,
The stand device according to any one of claims 1 to 5, wherein the storage battery is housed inside the cylindrical body, and the storage battery is connected to the light emitting unit and the air flow generating unit. It further has a guide member that is closely housed inside the tubular body.
The guide member is formed to have a substantially U-shaped cross section having a pair of side panels and a bottom panel.
The stand device according to any one of claims 1 to 6, wherein the light emitting unit and the air flow generating unit are fixed to the bottom panel of the guide member along the axial direction of the cylindrical body. A belt having a stand device and a belt winding portion for winding a belt or a belt locking portion for locking the belt, and the belt winding portion or the belt locking portion is fixed to the stand device. It ’s a partition,
The stand device has a pedestal portion and a cylindrical strut portion fixed to the pedestal portion.
The tubular strut portion has a tubular body, a light emitting portion housed inside the tubular body, and an air flow generating portion that generates an air flow inside the tubular body.
The light emitting portion is a belt partition having an ultraviolet generating portion that generates ultraviolet rays. The tubular body has an intake portion from which outside air is taken in and an exhaust portion from which air taken in from the intake portion is discharged, and the exhaust portion is located at a position farther from the pedestal portion than the intake portion. The belt partition according to claim 8, which is arranged. The ultraviolet light generating portion is formed by using an ultraviolet LED module in which a plurality of ultraviolet light emitting diodes that generate ultraviolet rays are arranged.
The belt partition according to claim 8 or 9, wherein the infrared LED module is arranged inside the tubular body along the axial direction of the tubular body.

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