KR102374583B1 - Ventilation register - Google Patents

Abstract

It provides a ventilation resistor that can capture ultra-fine contaminants with high probability while suppressing an increase in pressure loss. A ventilation register used in a natural air supply, comprising: an insertion tube installed by being inserted into a ventilation port of a building; a filter medium through which gas that has passed through the insertion tube passes; and a pre-filter between the insertion tube and the filter medium And, the filter is a nano-filter ventilation resistor is provided. According to the ventilation register of the present invention, it is possible to effectively ventilate by suppressing the entry of foreign matter into the room and suppressing the increase in pressure loss.

Description

VENTILATION REGISTER}

The present invention relates to a ventilation resistor installed in an indoor ventilation port of a building.

In order to ventilate a building, there is a case where a ventilation hole is installed in the wall on the inside side. Since such a ventilation port forms a through hole communicating indoors and outdoors, a ventilation register having a filter may be provided in order to prevent foreign substances such as outdoor dust and raindrops from entering the indoor space. Such a filter generally has a flat plate shape, and is disposed inside the ventilation hole or is installed to cover the indoor opening of the ventilation hole (see Patent Document 1, for example).

A ventilation register provided with an opening/closing mechanism capable of blocking the ventilation path of the ventilation port is used as necessary (see Patent Document 2 as an example). By providing such an opening/closing mechanism, the ventilation path of a ventilation port can be opened and closed freely, and it can be set as a ventilation register convenient for a user.

Patent Document 1: Japanese Unexamined Utility Publication No. 6-62017 Patent Document 2: Japanese Laid-Open Patent Publication No. 2005-282985

Recently, there are concerns about the health damage to the human body of minute particulate matter floating in the atmosphere. The minute particulate matter easily enters the deep inside of the respiratory tract and is thought to have an effect on the respiratory system and the circulatory system. Current ventilation resistors cannot sufficiently capture these minute particulate matter.

The filter as described in patent document 1 has a small through-hole which forms the flow path of air. As the through hole is made smaller, it is possible to collect smaller foreign matter. However, if the through hole is made smaller, the air flow path becomes more clogged, and there is a problem that the pressure loss of the ventilation port increases. As a method of suppressing such an increase in pressure loss, it is conceivable to enlarge the ventilation or filter. However, in such a case, there exists a subject that the ventilation register itself becomes enlarged and it is easy to damage the aesthetics of the indoor side of a building.

Further, in the ventilation register as described in Patent Document 2, when ventilation is not performed, the ventilation port is closed with a cover structure, and when ventilation is performed, the ventilation register is ventilated by taking the cover structure out to the indoor side and separating it from the opening of the ventilation port. The furnace can be opened to an open state. Such a ventilation resistor has a manufacturing problem because of the large number of parts, such as a spring structure that assists in pushing the cover structure from the ventilation port side to the indoor side when changing from the closed state to the open state. In addition, a ventilation register that can be opened and closed is also used because the cover structure is made of two blades, but it has a complicated structure because a mechanism for moving the two blades with one lever is provided. Therefore, it is difficult to manufacture efficiently, and there is a subject also in terms of cost. Moreover, in these conventional ventilation registers, there is also a problem in use because the operator may need a strong force when operating the cover structure.

The present invention has been made in order to solve the above problems. That is, an object of the present invention is to provide a ventilation resistor capable of suppressing foreign matter from entering the room and suppressing an increase in pressure loss without increasing the size.

Another object is to provide a ventilation resistor which has a simple structure, has a small number of parts, and is easy to manufacture. And it aims at providing the ventilation register which is easy for a user to open and close operation.

In order to achieve the above object, the present invention is constituted as follows.

(Item 1)

A ventilation register used in a natural air supply, comprising:

Insertion passage to be installed by inserting into the ventilation hole of the building;

a pre-filter through which the gas that has passed through the insertion tube passes;

A ventilation register comprising a filter material made of nano-filters through which the gas that has passed through the pre-filter passes.

(Item 2)

The method of claim 1,

The nanofilter, a ventilation resistor having a fiber diameter of about 1 to about 250 nm, and a pore diameter of about 5 to 10 μm.

(Item 3)

3. The method of claim 2,

The nanofilter has a pitch of about 3 to about 10 mm, and pleats having a mountain height of about 5 to about 40 mm.

(Item 4)

4. The method according to any one of claims 1 to 3,

A ventilation register having a backspace between the pre-filter and the insertion passage.

(Item 5)

5. The method of claim 4,

The backspace is about 5mm or more of the ventilation resistor.

(Item 6)

6. The method according to any one of claims 3 to 5,

A ventilation register in which the nano-filter collects about 70% or more of fine particles having a particle diameter of 0.5 to 1 μm with respect to an airflow having a linear velocity of 2.5 m/sec in the ventilation port.

(Item 7)

7. The method of claim 6,

The ventilation register is for a ventilation port with a diameter of 100 mm, and the pressure loss coefficient of the ventilation register is 180 or less.

(Item 8)

8. The method of claim 7,

A ventilation resistor having a pressure loss coefficient of 80 or less of the ventilation resistor.

(Item 9)

7. The method of claim 6,

The ventilation resistor is for a ventilation port with a diameter of 150 mm, and the pressure loss coefficient of the ventilation resistor is 120 or less.

(Item 10)

10. The method of claim 9,

A ventilation resistor having a pressure loss coefficient of 60 or less of the ventilation resistor.

(Item 11)

* according to any one of claims 7 to 10,

The cross-sectional area of the nano-filter is about 2.0 to about 2.7 times the cross-sectional area of the ventilation register.

(Item 12)

A filter system for installation in a ventilation register used in a natural air supply, the filter system comprising a filter medium and a pre-filter, the filter of the filter medium is a nano-filter,

The nano filter,

having a fiber diameter of about 1 to about 250 nm, and a pore diameter of about 5 to 10 μm,

having pleats with a pitch of about 3 to about 10 mm, and a peak height of about 5 to about 40 mm,

The filter system is

A filter system that collects about 70% or more of particulates with a particle diameter of 0.5 to 1 μm with respect to an airflow with a linear velocity of 2.5 m/sec in the ventilation port.

(Item 13)

Insertion passage to be installed by inserting into the ventilation hole of the building;

A face portion capable of moving forward and backward with respect to the indoor opening of the insertion tube;

A ventilation resistor comprising: a cylindrical pleated filter having a plurality of pleated portions arranged in parallel along a circumferential direction;

A ventilation register, characterized in that the one-side open end of the cylindrical pleated filter is provided on the back surface of the face portion.

(Item 14)

14. The method of claim 13,

A ventilation register having a holding portion in which the face portion holds the cylindrical pleated filter slidably with respect to the insertion tube.

(Item 15)

15. The method of claim 14,

A ventilation register having a ventilation gap portion through which air passing through the cylindrical pleated filter passes between the cylindrical pleated filter held by the holding portion and an inner peripheral surface of the insertion tube.

(Item 16)

16. The method according to claim 14 or 15,

The ventilation register in which the said holding|maintenance part has a sealing part between the cylindrical part of the said insertion cylinder.

(Item 17)

17. The method according to any one of claims 13 to 16,

The tubular pleated filter is a ventilation resistor having a tapered shape from the outdoor side toward the indoor side.

(Item 18)

18. The method according to any one of claims 13 to 17,

A ventilation register having a rectifying dome formed in the shape of an awl protruding toward the opening on the outdoor side of the insertion tube on the back surface of the face portion.

(Item 19)

19. The method according to any one of claims 13 to 18,

The face portion has a seal portion for fixing the cylindrical pleated filter and sealing a gap between the face portion and the cylindrical pleated filter.

(Item 20)

The insertion passage installed in the ventilation opening of the building;

a cover body installed on the indoor side of the insertion tube;

A first wing body and a second wing body installed in a vent passage inside the insert tube, wherein the first wing body and the second wing body are rotatably supported inside the insert tube, and each wing body A first wing body and a second wing body for opening and closing the air passage by rotational movement,

and a rotationally movable installation shaft installed in the insertion tube or the cover body;

a pressing piece portion having a pressing portion held by the first blade body so as to be displaceable in the radial direction of the insertion tube along the plate surface of the first blade body that rotates at a position spaced apart from the installation shaft portion;

A ventilation register comprising: a connecting piece that is pivotally supported by the first wing body at one end, and the other end is pivotally supported by the second wing body, so as to connect the wing bodies in an interlocking manner.

(Item 21)

21. The method of claim 20,

The first wing body rotates by being pressed by the pressing portion, the connecting piece interlocks with the rotational movement of the first wing body, and furthermore, by rotating the second wing body in conjunction with the connecting piece, the first blade Ventilation register, characterized in that the object and the second wing body rotate in an opening direction or a closing direction to open and close the ventilation port.

(Item 22)

22. The method according to claim 20 or 21,

The pressing piece portion is disposed between the first installation shaft portion as the installation shaft portion, the second installation shaft portion, and the first installation shaft portion and the second installation shaft portion, and protrudes toward the intersection direction with respect to the axial direction of the pressing piece portion having a protrusion,

The first installation shaft portion and the second installation shaft portion are disposed on the rotational axis of the pressing piece portion,

Ventilation register in which the pressing part is disposed on the protruding end side of the protrusion.

(Item 23)

23. The method according to any one of claims 20 to 22,

A ventilation register comprising the pressing part and the installation shaft part as a single member.

(Item 24)

24. The method according to any one of claims 20 to 23,

The ventilation register having the first blade body, a blade piece and a holding portion for movably holding the pressing portion of the pressing piece portion between the blade piece.

(Item 25)

25. The method according to any one of claims 20 to 24,

The press piece part is a ventilation register having an operation part protruding from the cover body.

That is, the present invention has a plurality of pleats arranged in parallel along the circumferential direction with respect to a ventilation register having an insertion tube installed by being inserted into a ventilation port of a building, and a face portion capable of moving forward and backward with respect to the indoor opening of the insertion tube. There is provided a ventilation resistor comprising a cylindrical pleated filter, wherein one open end of the cylindrical pleated filter is provided on the back surface of the face portion.

In the present invention, by forming the filter in a pleated shape, a filter having a larger surface area can be disposed in a limited space. In this way, by providing the pleated filter having a larger surface area, an increase in pressure loss can be suppressed without increasing the overall size of the ventilation resistor, and smooth ventilation can be performed.

Moreover, by making such a pleated filter into a cylindrical shape, compared with the case where it is set as a simple flat-panel pleated filter, the exclusive area in the wall surface of a building can be made small. Furthermore, since the cylindrical pleated filter can be moved forward and backward relative to the insertion tube by following the face portion, the amount of exposure of the cylindrical pleated filter to the indoor side can be adjusted by changing the position of the face portion with respect to the insertion tube, thereby adjusting the ventilation amount. .

The face portion of the present invention may have a holding portion that holds the cylindrical pleated filter slidably with respect to the insertion tube.

By doing in this way, it is possible to hold the cylindrical pleated filter so as not to drop off from the insertion tube. Further, for example, it is possible to easily perform operations such as inserting a cylindrical pleated filter inside the insertion tube to close the ventilation hole, or sliding the cylindrical pleated filter out of the insertion tube to open the ventilation hole.

Between the cylindrical pleated filter held by the holding portion of the present invention and the inner circumferential surface of the insertion tube, a ventilation gap portion through which air passing through the cylindrical pleated filter passes may be provided.

In this way, the flow path of the air passing through the cylindrical pleated filter can be secured by the ventilation gap portion. Therefore, since air can enter the room smoothly, an increase in pressure loss can be suppressed.

The holding part of the present invention may be provided with a sealing part between the cylindrical part and the cylindrical part.

By doing in this way, it can be made difficult to generate|occur|produce a situation, such as air which has not passed through a filter leaking and entering the indoor side from between a filter and a face part.

The cylindrical pleated filter of the present invention may have a shape that tapers from the outdoor side toward the indoor side.

In this way, an annular ventilation gap portion can be provided between the cylindrical pleated filter and the insertion passage so as to circumferentially the outer periphery of the cylindrical pleated filter. Accordingly, it is possible to allow the air that has passed through the cylindrical pleated filter to enter the room more smoothly.

The face portion of the present invention may have a rectifying dome portion protruding toward the opening on the outdoor side of the insertion tube on the back surface.

The shape of the rectifying dome can be any shape within a range that can smoothly guide the air entering the insertion tube to the cylindrical pleated filter. Preferably it is an awl shape, More preferably, it is conical shape. By installing the rectifying dome, air flows smoothly along the shape of the rectifying dome, so it is possible to prevent situations such as air hitting the back of the face and turbulence occurring inside the insertion tube, thereby suppressing an increase in pressure loss. there is.

The face portion of the present invention has a seal portion that fixes the cylindrical pleated filter and seals a portion between it and the cylindrical pleated filter.

* By doing this, it is possible to make it difficult to cause a situation such as air containing foreign matter entering the room from between the face portion and the cylindrical pleated filter.

The cylindrical pleated filter of the present invention may be made of a filter medium having a through-hole having a size of 0.3 µm or less.

By doing in this way, for example, entry of foreign substances, such as microscopic pollutants such as PM 2.5 and PM 0.5, into the interior can be suppressed.

In addition, the present invention is provided with an insertion tube installed in a ventilation port of a building, a cover body installed on the indoor side of the insertion tube, and a first wing body and a second blade body installed in the internal ventilation passage of the insertion tube, The first wing body and the second wing body are rotatably supported in the inside of the insert cylinder, and with respect to the ventilation register that opens and closes the ventilation path by rotation of each wing body, rotational movement is possible installed in the insert cylinder or the cover body. A pressing piece portion having an installation shaft and a pressing portion held by the first blade body so as to be displaceable in the radial direction of the insertion tube along the plate surface of the first blade body rotating at a position spaced apart from the installation shaft portion; It is pivotally supported by the first wing body and the other end is pivotally supported by the second wing body, so that the wing body is provided with a connecting piece that connects the wing bodies in an interlocking manner. It is characterized in that the first wing body and the second wing body rotate in the closing direction or the opening direction by interlocking the rotational movement of the first wing body, and furthermore, the second wing body rotates in conjunction with the connecting piece to open and close the ventilation port. Ventilation resistors are provided.

According to the present invention, by rotating the pressing piece, the pressing portion presses and rotates the first wing body, and furthermore, it is possible to rotate the second wing body through the connecting portion. Therefore, the opening/closing operation of the ventilation passage can be performed only by a simple operation of rotating the pressing piece portion. In addition, since the number of parts can be reduced as compared with the conventional ventilation resistor in which the cover structure is drawn toward the indoor side, it can be made into a ventilation resistor having a simpler structure, easy to manufacture, and advantageous in terms of cost.

The pressing piece portion of the present invention is disposed between the first installation shaft portion as the installation shaft portion, the second installation shaft portion, and the first installation shaft portion and the second installation shaft portion, and the direction of intersection with the axial direction of the pressing piece portion is It may have a protrusion protruding toward it, the first mounting shaft portion and the second mounting shaft portion being disposed on the rotational axis of the pressing piece portion, and the pressing portion being disposed on the protruding end side of the projection portion.

By setting it as such a structure, the holding part which can press down the 1st wing body reliably, making a holding piece part into a simpler structure can be formed.

The pressing portion and the installation shaft portion of the present invention may be made of a single member.

By making the pressing piece part such a structure, compared with the case where the pressing piece part consists of a plurality of members, the force which rotates the pressing piece part is transmitted smoothly to the 1st wing body, and rotational movement can be made easy. Therefore, the operator can perform the opening/closing operation of the 1st wing body and the 2nd wing body with a lighter force.

The 1st wing body of the said this invention may have a wing piece and the holding|maintenance part which hold|maintains the press part of a press piece part between the said wing piece movably.

By having such a holding part, the 1st wing body can be rotated in an opening direction or a closing direction by pressing the blade piece or holding part of the 1st wing body. In addition, since the holding part can hold the pressing part in a movably manner, the rotational axis of the first wing body and the pressing piece part are different, and even if the position of the pressing part is shifted with respect to the first blade body during rotational motion, the holding part is sure to hold the pressing part. can continue to hold.

The pressing piece portion of the present invention may be provided with an operation portion protruding from the cover body.

Thereby, since the operator can easily contact the operation part, the rotational motion operation of a 1st blade piece and a 2nd blade piece can be performed easily.

According to the ventilation register of the present invention, it is possible to effectively ventilate by suppressing the entry of foreign matter into the room and suppressing the increase in pressure loss.

According to the ventilation resistor of the present invention, it is possible to provide a ventilation resistor that has a small number of parts and is easy to manufacture. Further, according to the present invention, it is possible to provide a ventilation register that can be opened and closed easily for an operator and is easy to operate for an operator.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the ventilation register of 1st Embodiment.
FIG. 2 is a side view showing the second ventilation resistor of FIG. 1 .
FIG. 3 is a rear view showing the first ventilation resistor of FIG. 1 .
4 is a cross-sectional view taken along the arrow SA-SA of FIG. 2 .
Fig. 5 is a cross-sectional view showing a state in which the opening on the inner side of the insertion tube of Fig. 4 is closed.
6 is an explanatory cross-sectional view showing an air flow path.
Fig. 7 is a front view showing a face part of a modified example, in which an exploded view (a) shows an example of a substantially circular face along the outer diameter of the insertion tube, and (b) shows an example of a substantially triangular face part.
It is a perspective view which shows the front, left side, and plane of the ventilation register of 2nd Embodiment.
9 is a perspective view showing the front, right side, and bottom surface of the ventilation register of FIG.
Fig. 10 is a front view of the ventilation register of Fig. 8 in a closed state;
Fig. 11 is a front view of the ventilation register of Fig. 8 in an open state;
Fig. 12 is a rear view of the ventilation register of Fig. 8 in a closed state;
13 is a rear view of the ventilation resistor of FIG. 8 in an open state;
14 is a front view showing the rotational axis of the first wing body of the ventilation register of FIG. 8, the rotational axis of the second wing body, and the rotational axis of the pressing piece.
FIG. 15 is a front perspective view showing an opening/closing structure of the ventilation register of FIG. 8 in a closed state;
FIG. 16 is a front perspective view showing the opening/closing structure of the ventilation register of FIG. 8 in an open state.
Fig. 17 is a rear perspective view showing an opening/closing structure of the ventilation register of Fig. 8 in a closed state;
FIG. 18 is a bottom view showing the opening/closing structure of the ventilation register of FIG. 8 in a closed state.
19 is a bottom view showing the opening/closing structure of the ventilation register of FIG. 8 in an open state.
20 is a view showing a ventilation resistor equipped with a nano-filter.
21 is a view showing a ventilation resistor installed in an existing indoor resistor with a cover including a nano-filter and a pre-filter covered.
22 is a pressure loss curve diagram between a ventilation resistor set with a conventional electrostatic filter and a ventilation resistor set with two types of nanofilters subjected to pleat processing of three different pitches.
23A is a view showing time series changes in pressure loss of an electrostatic filter, a micro filter, and a nano filter.
23B is a diagram illustrating a comparison of the collection efficiencies of an electrostatic filter, a micro filter, and a nano filter.
24 is a view showing the results of examining the effect of the backspace on the pressure loss.
25 is a diagram illustrating a method for measuring a pressure loss.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the accompanying drawings, if necessary, by way of example embodiments. Throughout this specification, expressions of the singular form should be understood to include the concept of the plural form as well, unless specifically stated otherwise. In addition, unless otherwise indicated, it should be understood that the terms used in this specification are used with the meaning normally used in the field. Accordingly, unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. In case of conflict, the present specification (including definitions) controls.

(Justice)

As used herein, the term 'nanofilter' refers to a filter including at least a part of nanofibers. As used herein, the term “nanofiber” refers to a fiber having a fiber diameter of 1 to 800 nm or less. The nanofibers may be in which single fibers are dispersed, in which single fibers are partially bonded, or in an aggregate (eg, in the form of a bundle) in which a plurality of single fibers are aggregated.

In the present specification, the term 'fiber diameter' refers to observing the fiber collected from the filter medium with an optical microscope, measuring the true circular reduced fiber diameter for 30 fibers, and measuring the sum of the measured true circular reduced fiber diameters It is obtained by dividing by the number of fibers.

In the present specification, the 'pore diameter' refers to the filter by a pore diameter distribution analyzer (eg, an automatic pore diameter distribution analyzer pump porometer (PERM POROMETER) manufactured by Porous Materials Inc.). It refers to the measured mean flow pore size.

In the present specification, the 'collection efficiency' refers to the number of particles of a specific size upstream and downstream of the filter with a particle counter (eg, TSI Inc. particle counter (model 3771)),

Collection efficiency = 1- (number of downstream particles / number of upstream particles) × 100

is the value calculated by

In the present specification, the 'particle diameter' of the particle means the diameter of a circle circumscribed by the particle when the particle is viewed from an arbitrary direction. The particle diameter can be measured by, for example, taking a picture with a magnification of 1000 times or more with a microscope such as a scanning electron microscope. As the average particle diameter, 50 or more particles are randomly selected, and the average particle diameter is taken as the average value of those particle diameters. Hereinafter, in the present specification, 'particle diameter' means all 'average particle diameter'.

In the present specification, 'PM 2.5' refers to a micro-particulate material having a particle diameter of 2.5 μm or less.

(details)

For indoor ventilation, there are mainly three types of systems. The first is a type 1 ventilation system in which both supply and exhaust are forcibly performed by a machine (electric fan). The second is a type 2 ventilation system in which natural ventilation is performed on the exhaust side and mechanical ventilation is performed on the supply side forcibly. This is used in a clean room etc. in many cases, and is hardly used for a house. The third is a type 3 ventilation system that forcibly exhausts the air through mechanical ventilation and supplies that amount to the natural air supply (indoor ventilation register).

Unlike the air supply in the mechanical ventilation in the type 1 ventilation system or the type 2 ventilation system, the supply port in the type 3 ventilation system supplies air by natural air supply. Filters have traditionally been considered to have low pressure loss. This is because, in the third type ventilation system, if the pressure loss of the ventilation resistor is large, the required motor capacity of the electric exhaust fan increases, and there is also a risk of decompression in the room. In addition, the ventilation register of the third type ventilation system is not suitable for the point that the air volume of the air supply port of the type 1 ventilation system and the type 2 ventilation system is constant while the air volume of the air supply port of the type 3 ventilation system fluctuates greatly. It is different from the air inlet of class 1 and class 2 ventilation systems.

The present inventors have unexpectedly discovered that a nanofilter material can be used for the ventilation register in such a third type ventilation system. At first glance, it is considered in the field that the nano-filter material is not different from the nonwoven fabric and has a high surface density, so it cannot be used as a ventilation resistor for a third-class ventilation system from the viewpoint of pressure loss. For example, in recent years, in a building room such as a mansion where a third type ventilation system is generally used, because the airtightness of the room itself is high, if the pressure loss performance of the ventilation resistor is poor, a large differential pressure is generated inside and outside the room, In some cases, it may become impossible to open the door with the power of As such, with respect to the ventilation register of the third type ventilation system, the pressure loss is particularly problematic. In fact, only electrostatic filters and microfilters using fibers having a fiber diameter of at least 1 μm are used for the ventilation registers of the third type ventilation system.

However, the present inventors have found that, by using the nanofilter material for the ventilation resistor, it is comparable to the conventional ventilation resistor in pressure loss, and the collection efficiency of minute particulate matter can be remarkably increased.

In the present invention, the fiber diameter of the nanofilter used in the ventilation resistor of the natural air supply is about 1 to about 800 nm, about 1 to about 500 nm, about 1 to about 300 nm, about 1 to about 250 nm, about 30 to about 800 nm, It may be about 30 to about 500 nm, about 30 to about 300 nm, about 30 to about 250 nm, preferably about 50 to about 250 nm, and more preferably about 50 to about 150 nm.

In the present invention, the pore diameter of the nanofilter used in the ventilation register of the natural air supply is about 3 to about 15㎛, preferably about 5 to about 7㎛ may be.

In a nanofilter, a person skilled in the art can adjust the pressure loss and the collection efficiency of micromaterials by the balance between the pore diameter and the fiber diameter, in a preferred embodiment, the nanofilter of the present invention has a thickness of about 50 to about 150 nm. It has a fiber diameter and a hole diameter of about 3 to about 15 μm.

The nanofilter of the present invention may be formed of any material. As such materials, polytetrafluoroethylene (PTFE), polyethylene (PE), polypropylene (PP), polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polyamide (PA), polyacrylonitrile (PAN), polyvinylidene fluoride (PVdF), polyvinyl alcohol (PVA), polyurethane (PU), and the like, but is not limited thereto. In a preferred embodiment, the nanofilter of the present invention may be made of PTFE.

The nanofilter of the present invention may be provided with an air permeable support layer on the upper surface and/or the lower surface as needed. The nanofilter of the present invention may further include a second filter layer.

The nanofilter of the present invention may have a thickness of about 3 to about 50 μm, more preferably about 3 to about 20 μm, and still more preferably about 3 to about 10 μm. For example, it is known that glass fiber is used as a filter with high collection efficiency, but such a filter generally has a thickness exceeding 100 μm in many cases. From the viewpoint of the design of the ventilation resistor, a thinner one is preferable.

In the present invention, a ventilation resistor excellent in collection efficiency and pressure loss may be provided by covering the nanofilter over an existing indoor ventilation resistor and installing it in the third-class ventilation indoor resistor. In this way, it is possible to simply install a high-performance filter in many existing buildings.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described based on drawing.

(First embodiment [Figs. 1 to 6])

The ventilation register 1 of the present invention is installed on the indoor side of the ventilation hole 2 installed on the inner wall 5 of the building, and is used to suppress the intrusion of foreign substances such as dust or raindrops from the outdoors into the interior. Such an indoor register 1 is provided with the insertion cylinder 3 and the face part 4, as shown in FIGS.

[Insert tube]

The insertion cylinder 3 consists of substantially cylindrical shape, as shown in FIG. The air 11a that has entered the ventilation port 2 can pass through the inside of the insertion tube 3 . In addition, the insertion tube 3 can be installed by being inserted into the ventilation hole 2 opened in the inner wall 5 of the building. An outward facing flange 6 is provided from the indoor open end 3a of the insertion tube 3, and a screw fixing part S is provided in this outward facing flange 6. And, the outward-facing flange 6 has an outer frame part 6a that follows its outline. The material of the insertion tube 3 can take any material. For example, metals, such as aluminum and stainless steel, may be sufficient and plastic materials, such as resin, may be sufficient. In a preferred embodiment, the insertion tube 3 is provided with a resin material to be aged, but the present invention is not limited thereto. The shape of the insertion tube can take any form as long as it is a cylindrical body. For example, a triangular cylinder may be sufficient, a quadrangular cylinder may be sufficient, and a polygonal cylinder may be sufficient and a cylindrical body may be sufficient.

[face part]

* The face portion 4 is, as shown in Figs. 1 to 5, the flat plate portion 7, the rectifying dome portion 7b, and the back surface of the flat plate portion 7 (the surface facing the insertion tube 3). A cylindrical pleated filter (8) to be installed and a holding portion (9) for the insertion tube (3) are provided. On the other hand, in this embodiment, the case where a pleated filter is used as the cylindrical filter is exemplified, but it should be understood that pleated processing is not necessarily required, and that a case where a cylindrical filter without pleat processing is used is also within the scope of the present invention. The material of the face part 4 can take any material. For example, metals, such as aluminum and stainless steel, may be sufficient and plastic materials, such as resin, may be sufficient. In a preferable embodiment, although the face part 4 is provided with the resin material which weight reduction is achieved, this invention is not limited to this.

The flat plate portion 7 has a substantially square thin plate shape, and a handle portion 7a made of a thin plate is provided on the surface side exposed to the indoor side in a state of being installed on the inner wall 5 of the building. The face part 4 is slidably movable in the forward/backward direction with respect to the insertion cylinder 3 . Therefore, the user can take out the face part 4 from the insertion tube 3 to the indoor side by picking up the handle part 7a with a finger and pulling it indoors. On the other hand, this flat plate part 7 is made in substantially the same shape as the outer shape of the outward flange 6, and in a state in which the flat plate part 7 is slid to the outward flange 6 side, the It can be accommodated inside the outer frame part 6a.

The rectifying dome portion 7b is provided at a substantially central position on the back surface of the flat plate portion 7 and has a substantially conical shape protruding toward the outdoor open end 3b of the insertion tube 3 . It is formed so that the ratio of expansion increases as it goes down from the tip side (outdoor side) to the base side (indoor side) (refer FIGS. 4-6).

Moreover, on the back surface of the flat plate part 7, the support part 12 which goes round the outer periphery of the indoor side open end 8b side of the cylindrical pleated filter 8 is formed. And, the outer shape of the support portion 12 is formed to follow the inner shape of the insertion tube (3). The support part 12 may come in contact with the inner surface of the insertion tube 3 to support the face portion 4 from the inside of the insertion tube 3 (refer to FIG. 5 ).

The cylindrical pleated filter 8 is made of a cylindrical filter material, and has a plurality of pleated portions 8a arranged in parallel along the periphery thereof. Such a cylindrical pleated filter 8 is composed of a pleated filter in which a plurality of pleated portions 8a are provided by bending one filter medium. By providing the plurality of pleated portions 8a in this way, it is possible to use a filter having a larger surface area within a limited space as compared to a case where a flat filter is simply used. Therefore, it can be set as the ventilation resistor 1 which can suppress a pressure loss. On the other hand, the size of the filter medium to be used can be variously changed according to the size of the ventilation register 1 or the target ventilation performance. Therefore, according to the size of the filter medium and the size of the insertion tube 3, the number of pleated portions 8a included in the cylindrical pleated filter 8 can be variously set.

Furthermore, in the first embodiment, the cylindrical pleated filter 8 is formed by bending such a pleated filter in the parallel direction of the pleated portions 8a to form a cylindrical shape. The outer diameter of the cylindrical pleated filter 8 is formed slightly smaller than the inner diameter of the insertion tube 3 . By making the pleated filter cylindrical, it is possible to reduce the total oil area on the inner wall 5 as compared with a simple flat-plate pleated filter. Therefore, the ventilation register 1 can be made compact as a whole. In addition, when not in use, since the cylindrical pleated filter 8 can be accommodated inside the insertion tube 3, it is possible to prevent deterioration of indoor aesthetics. In the first embodiment, the cylindrical pleated filter 8 is a cylindrical body, but the present invention is not limited to this. The cylindrical pleated filter 8 can take any cylindrical shape according to the cylindrical shape of the insertion tube 3 . For example, a triangular cylinder may be sufficient, a quadrangular cylinder may be sufficient, and a polygonal cylinder may be sufficient.

Moreover, the cylindrical pleated filter 8 is provided so that it tapers from the outdoor open end 8c side toward the indoor open end 8b side, and this thin indoor open end 8b side It is being fixed to the back surface of this face part (4). A contact portion between the indoor open end 8b and the face portion 4 is sealed with a seal portion 10a such as an adhesive. In this way, since it is possible to prevent a gap between the face portion 4 and the cylindrical pleated filter 8 from being generated, the vent chamber 3c of the cylindrical pleated filter 8 is opened from the open end 3b of the insertion tube 3 . Air 11a containing foreign matter entering the air does not leak into the room, and only purified air can pass through the cylindrical pleated filter 8 with certainty. In addition, by installing such a cylindrical pleated filter 8 on the face part 4 exposed on the indoor side, for example, the filter medium can be replaced easily compared to the case where it is installed inside the insertion tube 3 . .

As described above, since the cylindrical pleated filter 8 has a shape that tapers from the outdoor open end 8c to the indoor open end 8b, there is a ventilation gap between the inner peripheral surface of the insertion tube 3 and the cylindrical pleated filter 8. A portion 11 is formed. Therefore, since the air 11a passing through the cylindrical pleated filter 8 can form a flow path in the ventilation gap 11, it can enter the room smoothly without blocking the path by the insertion tube 3 . Since the cylindrical pleated filter 8 has a tapered shape in this way, the ventilation gap 11 is provided in an annular shape so as to go around the outer periphery of the cylindrical pleated filter 8 . Further, the ventilation gap portion 11 is formed so as to be largely diffused from the outdoor side toward the indoor side. Accordingly, the air 11a entering the ventilation gap 11 can smoothly enter the indoor side without staying on the indoor open end 3b side of the insertion tube 3 .

In the first embodiment, a filter material having a through hole smaller than the foreign matter to be collected is used as the filter medium. Recently, air pollution caused by microscopic pollutants such as PM 2.5, which is said to have a maximum particle diameter of about 2.5 μm, has become a social problem. You need to do it with a small hole. PM 2.5 is composed of microscopic contaminants of 2.5 μm or less, so for example, by using a filter material having a through hole of about 0.3 μm as a filter material, there is a high probability of removing not only PM 2.5 but also micro particles such as PM 0.5 by trapping it, it is possible to suppress intrusion into the room. A preferred filter medium is the above-described nano filter medium, but is not limited thereto. When it is not necessary to collect foreign matter as small as this, a filter medium having a larger through hole may be used.

For example, by providing a water-repellent process to such a filter medium, the penetration of raindrops into an indoor can be suppressed. Therefore, it becomes unnecessary to cover the cover for blocking the penetration|invasion of foreign materials, such as raindrops, indoors, and it can be set as the ventilation register 1 with high convenience for a user.

The holding portion 9 has a ring shape, and is fixed to the outdoor open end 8c of the cylindrical pleated filter 8 . Further, the contact portion between the holding portion 9 and the outdoor open end 8c is sealed by a sealing portion 10b made of an adhesive or the like. In this way, the gap can be closed and foreign matter can be suppressed from entering the indoor side. And the pre-filter 13 is provided inside the holding|maintenance part 9. As shown in FIG. The pre-filter 13 is made of a filter material having a through hole larger than that of the filter material forming the cylindrical pleated filter 8, and foreign matter such as dust or raindrops with a large particle diameter that enters the ventilation hole 2 from the outside. can be captured. In the first embodiment, the holding portion 9 has a ring shape, but the present invention is not limited thereto. The shape of the holding part 9 can take any shape according to the shape of the inner wall of the insertion cylinder 3 .

A sealing portion 9a is provided on the outer periphery of the holding portion 9 . The sealing portion 9a is made of an elastic material such as rubber or packing, and the diameter is set to be slightly larger than the inner peripheral diameter of the insertion tube 3 . When the holding portion 9 is inserted into the insertion tube 3 , the sealing portion 9a is compressed and pressed against the inner surface of the insertion tube 3 . In this way, the portion between the inner circumferential surface of the insertion tube 3 and the holding portion 9 can be sealed, so that the air 11a that has not passed through the filter medium can be suppressed from entering the room from such a portion. However, the sealing portion 9a is not completely fixed while sealing the portion between the inner peripheral surface of the insertion tube 3 and the holding portion 9, and can slide with respect to the inner surface of the insertion tube 3 . Accordingly, such a sealing portion 9a does not impede the sliding movement of the face portion 4 with respect to the insertion tube 3 .

[Description of how to use]

As shown in Figs. 4 and 5, the ventilation resistor 1 is provided in the ventilation port 2 provided on the inner wall 5 of the building. Specifically, the inner diameter of the vent 2 is installed so as to be about the same as the outer diameter of the insertion tube 3 , and the insertion tube 3 is inserted into the ventilation hole 2 . A packing (not shown) is disposed on the outer peripheral surface of the insertion tube 3 to fill the gap with the inner peripheral surface of the ventilation port 2 . Thereafter, by screwing the screwing portion S of the outward flange 6 , the ventilation resistor 1 can be fixed with respect to the inner wall 5 .

In this way, with respect to the ventilation register 1 provided in the ventilation port 2, the flat plate portion 7 of the face portion 4 is pushed into the outward flange 6 side, whereby the cylindrical pleated filter 8 is inserted into the insertion tube ( 3) can be inserted. In this way, by setting the flat plate portion 7 to a closed state so as to block the indoor-side open end 3a of the insertion tube 3, it is possible to prevent outside air from entering the room. In this way, when not in use, by inserting the cylindrical pleated filter 8 into the insertion tube 3, the amount of protrusion toward the indoor side can be reduced, and the aesthetics of the interior can be prevented from being damaged. On the other hand, by taking out the flat plate part 7 so that it may be spaced apart from the outward flange 6, the indoor opening end 3a can be opened and ventilation can be performed. Moreover, it is also possible to adjust the ventilation amount without taking out the face part 4 completely.

[Control method for increasing pressure loss]

The ventilation register 1 of the first embodiment is provided with the cylindrical pleated filter 8 having a plurality of pleated portions 8a as described above, in a limited space as compared with the case of having a flat-panel pleated filter. can increase the surface area. Accordingly, an increase in pressure loss can be suppressed.

Moreover, the ventilation resistor 1 of 1st Embodiment has the rectification|straightening dome part 7b as mentioned above. The air 11a entering the ventilation chamber 3c is smoothly guided toward the cylindrical pleated filter 8 side along the inclination of the rectifying dome 7b as shown in FIG. 6 . Therefore, it is possible to prevent a situation in which the air 11a stays inside the ventilation chamber 3c and a turbulence occurs, so that an increase in the pressure loss can be suppressed. In particular, as described above, the rectifying dome 7b of the first embodiment is formed so that the diffusion rate increases as it goes down from the tip side (outdoor side) to the base side (indoor side) (Figs. 4 and 5). see). In this way, as compared to the case where the air 11a passes smoothly on the surface of the rectification dome part 7b, compared to the case where it is installed in a conical shape that spreads evenly from the tip side to the base side, the outer periphery of the rectification dome part 7b It is guided to the side of the cylindrical pleated filter 8 disposed in the ? (refer to Fig. 6. On the other hand, in Fig. 6, the description of the pleated portion 8a is partially omitted to show the flow of the air 11a).

As mentioned above, by using the ventilation resistor 1 of 1st Embodiment, foreign materials, such as a smaller pollutant, can also be collected. Moreover, since the increase in pressure loss can also be suppressed, not only forced ventilation but natural ventilation can be performed smoothly.

Variant [Fig. 7]:

In the first embodiment, an example in which the face portion 4 and the outward-facing flange 6 are substantially square was shown. However, the cylindrical pleated filter 8 of the first embodiment has a cylindrical shape having a substantially circular cross section with a diameter substantially the same as that of the insertion tube 3, and is inserted into the insertion tube 3, so that the face portion 4 and the outward flange It does not affect the shape of (6) very much. Therefore, if only the screw fixing part S is provided on the outward-facing flange 6, for example, the face part 4 and the outward-facing flange 6 are made into the substantially circular ventilation resistor 14 (FIG. 7). (a)), the substantially triangular ventilation resistor 15, etc. (refer FIG.7(b)), the shape of the face part 4 and the outward flange 6 can be designed freely. Therefore, it can be set as the ventilation register 1 which shows a higher aesthetics.

(Second embodiment [Figs. 8 to 19])

Hereinafter, the ventilation register 51 of 2nd Embodiment is demonstrated, referring drawings.

On the other hand, in this specification, the parallel direction of the first wing body 53 and the second wing body 54 of the ventilation resistor 51 is the left-right direction X, the ventilation direction of the ventilation resistor 51 is the front-back direction Y, A height direction along the rotational axis A1 of the first wing body 53 and the rotational axis A2 of the second wing body 54 included in the ventilation resistor 51 is described in the Z-direction. However, this description does not limit the method of use or the installation place of the ventilation register 51 . In addition, the structure of the 1st wing body 53 and the 2nd wing body 54 using the left-right direction X and the front-back direction Y, and the description of the operation method, unless otherwise stated, the 1st wing body 53 and the 2nd It is described based on the case where the wing body 54 is in a closed state.

The ventilation register 51 of the second embodiment is provided in a ventilation port provided on an inner wall of a building, and can open and close the ventilation port. As shown in Figs. 8 and 9, the ventilation register 51 includes an insertion tube 52, a cover body 57, and an opening/closing structure 51A. In particular, in the second embodiment, the ventilation resistor 51 has a rotational axis A1 of the first wing body 53 and a rotational axis A2 of the second wing body 54 with respect to the ventilation opening in a vertical direction. It is provided so as to follow, and the side on which the operation part 56c2 is installed in the pressing piece part 56 is arrange|positioned at the lower side, and the other end side is arrange|positioned at the upper side. However, in the ventilation register 51, depending on the installation location, for example, the operation part 56c2 may be arranged on the upper side, and the rotational axis A1 of the first wing body 53 and the second wing body ( 54) may be provided so that the rotational axis A2 follows the direction crossing the vertical direction.

[Insert tube]

The insertion tube 52 consists of substantially cylindrical shape, as shown in FIG.8, FIG.9. The air entering the ventilation port may pass through the ventilation path R inside the insertion tube 52 . In addition, the insertion tube 52 may be installed by inserting it into a ventilation hole opened in the inner wall of the building. In 2nd Embodiment, although the case where the shape of the insertion cylinder 52 is substantially cylindrical shape is demonstrated, this invention is not limited to this. The shape of the insertion tube 52 may be any shape as long as it is a cylindrical body. For example, a triangular cylinder may be sufficient, a quadrangular cylinder may be sufficient, and a polygonal cylinder may be sufficient.

[Cover body]

The cover body 57 is formed so as to be diffused in the outer circumferential direction from the indoor opening 52a of the insertion tube 52 . Moreover, the cover body 57 has the outer frame part 57a which follows the external shape, and the cover part (not shown) which covers the indoor side of the insertion tube 52. As shown in FIG.

[Opening and closing structure]

The opening/closing structure 51A includes, as shown in FIGS. 15 to 17 , a first wing body 53 , a second wing body 54 , a connecting piece portion 55 , and a pressing piece portion 56 . .

[First wing body]

The first wing body 53 is formed in a substantially semicircular plate shape, and is pivotally supported with respect to the insertion tube 52 so as to be rotatable. Specifically, the first wing body 53 has a fixing portion 53a fixed to the inner upper surface of the insertion tube 52 and a fixing portion 53b fixed to the inner lower surface of the insertion tube 52 , Reference numeral 53 rotates around a rotational axis A1 connecting the fixed portion 53a and the fixed portion 53b as a center. This rotational shaft A1 is arrange|positioned at the center side of the insertion cylinder 52 rather than the center of the 1st blade body 53 in the left-right direction X. As shown in FIG. In 2nd Embodiment, although the case where the shape of the 1st blade body 53 is substantially semicircular is demonstrated, this invention is not limited to this. The shape of the first wing body 53 may be any shape as long as it is a shape along the circumference of the insertion tube 52 . For example, if the insertion tube 52 is a triangular cylindrical body, the first wing body 53 may be triangular, and if the insertion tube 52 is a rectangular cylindrical body, the first wing body 53 may have a quadrangular shape, and the insertion tube 52 If ) is a polygonal cylindrical body, the first wing body 53 may have a semi-polygonal shape.

As shown in FIG. 14, the 1st wing body 53 is inserted from the outer peripheral side outer peripheral side part 53A of the insertion cylinder 52 rather than the rotational axis A1 in the left-right direction X, and from the rotational axis A1. It has a center side center side part 53B of the cylinder 52. As shown in FIG. As described above, since the rotational axis A1 is disposed on the center side of the insertion tube 52 rather than the center of the first blade body 53 in the left-right direction X, it is located in the left-right direction X of the central side portion 53B. The length is formed shorter than the length in the left-right direction X of the outer peripheral side portion 53A. The outer peripheral side portion 53A and the central side portion 53B rotate in opposite directions when the first wing body 53 rotates about the rotational axis A1 as the center. That is, when the outer peripheral side portion 53A rotates to the outdoor side, the central side portion 53B rotates to the indoor side, and conversely, when the outer peripheral side portion 53A rotates to the indoor side, the center side portion 53B rotates to the outdoor side. .

As shown in FIG. 10, such a 1st blade body 53 has the blade piece 53c and the holding|maintenance part 53d provided in the plate surface of the blade piece 53c. The wing piece 53c is made of a plate-shaped part that opens and closes the ventilation path R. Further, the holding portion 53d has a substantially U-shape, and is formed to protrude from the outer peripheral side portion 53A to the indoor side. A movable gap 53e is formed between the holding portion 53d and the blade piece 53c, and the pressing portion 56a of the pressing piece portion 56 is disposed in the movable gap 53e. When the pressing piece portion 56 rotates, the pressing portion 56a can move within the movable gap 53e. Moreover, in this holding part 53d, the 1st protrusion part 53d1 which protrudes into the inside of the movable clearance gap 53e is formed on one end side in the left-right direction X, and similarly inside the movable clearance gap 53e on the other end side. A protruding second protrusion 53d2 is formed (FIG. 19). In the second embodiment, the holding portion 53d is substantially U-shaped, but the present invention is not limited thereto. For example, a substantially U-shape may be sufficient and a substantially V-shape may be sufficient.

As the outer peripheral portion 53A of the first wing body 53, on the plate surface on the outdoor side, as shown in Figs. ) is pivotally supported for rotational movement.

[Second wing body]

The second wing body 54 is formed in a substantially semicircular plate shape with the first wing body 53 and the carriage, and the end face 54c of the second wing body 54 and the end face of the first wing body 53 . A substantially circular flat plate portion for blocking the air passage R is formed by covering the indoor opening 52a of the insertion tube 52 with the end surfaces facing each other at 53f. In 2nd Embodiment, although the case where the shape of the 2nd blade body 54 is substantially semicircular is demonstrated, this invention is not limited to this. The shape of the second wing body 54, like the first wing body 53, may be any shape as long as it follows the outer circumference of the insertion tube 52. For example, if the insert tube 52 is a triangular cylindrical body, the second wing body 54 may have a triangular shape. If ) is a polygonal cylindrical body, the second wing body 54 may have a semi-polygonal shape.

The second blade body 54 is rotatably supported with respect to the insertion tube 52 similarly to the first blade body 53 . Specifically, the second wing body 54 has a fixing portion 54a fixed to the inner upper surface of the insertion tube 52 and a fixing portion 54b fixed to the inner lower surface of the insertion tube 52, and the second wing body 54 is Reference numeral 54 rotates about a rotational axis A2 connecting the fixed portion 54a and the fixed portion 54b as a center. This rotational axis A2 is disposed on the center side of the insertion tube 52 rather than the center of the second blade body 54 in the left-right direction X, and is located on the left-right direction X of the center side portion 54B. The length is formed shorter than the length in the left-right direction X of the outer peripheral side portion 54A. The rotational axis A2 of the second wing body 54 is arranged parallel to the rotational axis A1 of the first wing body 53 .

As shown in FIG. 14, the 2nd wing body 54 is from the outer peripheral side part 54A of the outer peripheral side of the insertion cylinder 52 rather than the rotational axis A2 in the left-right direction X, and from the rotational axis A2. It has a center side part 54B on the center side of the insertion cylinder 52. As shown in FIG. The outer peripheral side portion 54A and the center side portion 54B rotate in opposite directions when the second wing body 54 rotates about the rotational axis A2 as the center. That is, when the outer peripheral side portion 54A rotates to the outdoor side, the center side portion 54B rotates to the indoor side, and conversely, when the outer peripheral side portion 54A rotates to the indoor side, the center side portion 54B rotates to the outdoor side.

A fixing portion 54d, in which the second shaft support portion 55b of the pressing piece portion 56 is pivotally supported, is formed on the outer plate surface of the second wing body 54, which is the center side portion 54B. The fixing part 54d is formed in a concave-shaped structure provided on the plate surface of the outdoor side of the second wing body 54, and this fixing part 54d is located on the indoor side of the second wing body 54. It protrudes from the plate surface.

[connection part]

The connecting piece part 55 is made in the shape of a bar piece, and connects the first wing body 53 and the second wing body 54 . The connecting piece part (55) is provided on one end side and is an outer peripheral side part (53A) of the first wing body (53), and includes a first shaft support part (55a) that is axially supported on a plate surface on the outdoor side, and is provided on the other end side and is formed. It is a center side part 54B in the 2 blade|wing body 54, and has the 2nd shaft support part 55b which is pivotally supported by the plate surface of the exterior side.

[Pressure piece]

As shown in FIGS. 9-11, the pressing piece part 56 is formed by bending a rod, and has the 1st installation shaft part 56b, the 2nd installation shaft part 56c, and the protrusion part 56A. The material of the rod forming the pressing piece portion 56 may be any material. For example, hardened plastic resin etc. may be sufficient, wood may be sufficient, and metals, such as stainless steel and aluminum, may be sufficient.

The first and second installation shaft portions 56b and 56c are disposed on the same axis along the height direction Z, and are formed of a straight bar piece. At the upper end of the first installation shaft portion 56b, a rotational movement fixing portion 56b1 that is pivotally supported in a rotational manner with respect to the upper side of the inner surface of the outer frame portion 57a of the cover body 57 is provided. Below the second mounting shaft portion 56c, there is provided a rotational movement fixing portion 56c1 that is rotatably supported on the lower side of the inner surface of the outer frame portion 57a of the cover body 57 . The first installation shaft portion 56b and the second installation shaft portion 56c are formed to have the same length. In addition, the lower side of the rotation fixing portion 56c1 of the second mounting shaft portion 56c protrudes outwardly from the outer frame portion 57a of the cover body 57, and an operation portion 56c2 is provided at the lower end thereof. . The operation part 56c2 protrudes to the outside from the outer frame part 57a, and it becomes easy for an operator to operate.

The protrusion part 56A is formed between the 1st mounting shaft part 56b and the 2nd mounting shaft part 56c, and is formed in the substantially U-shaped protrusion shape in the substantially center in the height direction Z. A pressing portion 56a formed in a linear shape along the height direction Z is formed on the protruding end side of the projecting portion 56A. By providing the pressing portion 56a on the protruding portion 56A, the pressing portion 56a is centered on the rotational axis A3 of the pressing piece portion 56, and the first and second mounting shaft portions 56b and 56c) Rotational movement can be performed at a position spaced apart from the left and right X and front and rear Y directions. Therefore, the 1st wing body 53 can be pressed by the pressing piece part 56 alone, without providing another member to the pressing piece part 56. As shown in FIG. In the second embodiment, the protrusion 56A has a substantially U-shape, but the present invention is not limited thereto. A substantially U shape may be sufficient and the substantially V shape may be sufficient.

The longer the pressing portion 56a is provided in the height direction Z, the larger the area can be in contact with the blade piece 53c or the holding portion 53d. Therefore, since the pressure can be distributed over a large area, the pressing portion 56a can smoothly press the first wing body 53 .

The rotational movement shaft A3 of the pressing piece portion 56 is disposed on a shaft connecting the rotational movement fixing portion 56b1 and the rotational movement fixing portion 56c1. The rotational axis A3 of the pressing piece portion 56 and the rotational axis A1 of the first blade body 53 are provided at different positions in the left-right direction X and the front-rear direction Y. In particular, in the second embodiment, the rotational axis A3 of the pressing piece portion 56 is on the inside side of the rotational axis A1 of the first wing body 53 in the front-rear direction Y, and the insertion tube in the left-right direction X It is arranged on the outer peripheral side of (52).

[Explanation of the operation method when changing the ventilation register from the closed state to the open state]

First, the operation of opening the ventilation passage R will be described with reference to FIG. 18 . With respect to the ventilation resistor 51 in the closed state in which the 1st blade body 53 and the 2nd blade body 54 closed the ventilation path R, the operation part 56c2 is rotationally operated in the opening direction (arrow P1). ). By doing so, the pressing piece portion 56 rotates in the opening direction, and the pressing portion 56a presses the blade piece 53c of the blade body 53 in the closed state toward the outside (arrow P2). When the first blade body 53 rotates about the rotation axis A1 as a central axis, the outer peripheral side portion 53A of the first blade body 53 enters the inside of the insertion tube 52, and the center side portion 53B ) enters the interior. However, since the length in the left-right direction X of the center side portion 53B is formed shorter than the length in the left-right direction X of the outer peripheral side portion 53A, the amount of protrusion toward the interior side is shortened. In this way, the 1st wing body 53 will be in an open state.

As described above, the rotational axis A1 of the first wing body 53 and the rotational axis A3 of the pressing piece 56 are arranged at different positions in the left-right direction X and the front-rear direction Y. Therefore, as the pressing piece portion 56 and the first blade body 53 rotate, the pressing portion 56a of the pressing piece portion 56 moves in the left-right direction X with respect to the first blade body 53 ( 52), the position is shifted from the outer periphery side toward the center side. However, since the holding portion 53d is formed long along the left-right direction X, and the movable gap 53e is also formed long along the left-right direction X, the pressing portion 56a is formed with respect to the first wing body 53 . Even if the position shifts, the shift can be tolerated and the holding part 56a can be continuously held.

The connecting piece part 55 is pressed by the first wing body 53 to rotate, and the first shaft support part 55a moves to the outside (arrow P3). At the same time, the second shaft support portion 55b moves to the interior side, and pulls the center side portion 54B of the second wing body 54 toward the interior side (arrow P4). As a result, the outer peripheral side portion 54A of the second wing body 54 rotates toward the outdoor side, and the second wing body 54 is brought into an open state (arrow P5). Since the length in the left-right direction X of the center side portion 54B is formed shorter than the length in the left-right direction X of the outer peripheral side portion 54A as in the case of the first wing body 53, the amount of protrusion toward the interior is short. is lost Therefore, in an open state, the amount of protrusion toward the interior side of the 1st blade body 53 and the 2nd blade body 54 is short, and it can be set as the ventilation register 51 which does not impair indoor aesthetics.

As described above, in the holding portion 53d, a first protrusion 53d1 protruding into the movable gap 53e is formed. When moving the operation portion 56c2 from the closed state to the open state, the pressing portion 56a having the movable gap 53e moved can be fixed at a position beyond the first protruding portion 53d1. In this way, since the pressing piece portion 56 is fixed in the open position, the first blade body 53, the connecting piece portion 55, and the second blade body 54 are similarly maintained in the open state. In addition, since the operator can obtain a clicking feeling in the vicinity when the pressing portion 56a, which has moved inside the movable gap 53e, crosses the first protruding portion 53d1, it is a feeling of the hand that such fixing is reliably achieved. can be checked

As described above, the pressing piece portion 56, the first blade body 53, the connecting piece portion 55, and the second blade body 54 are displaced almost simultaneously. Therefore, the 1st wing body 53 and the 2nd wing body 54 can be easily opened like a hinged door only by the simple operation of rotating the operation part 56c2. Since the ventilation path R is opened in such an open state, ventilation can be performed sufficiently.

[Explanation of the operation method when changing the ventilation register from the open state to the closed state]

Next, the operation of closing the ventilation passage R will be described with reference to FIG. 19 . With respect to the ventilation register 51 in the open state in which the 1st blade body 53 and the 2nd blade body 54 opened the ventilation path R, the operation part 56c2 is rotationally operated in the closing direction (arrow). C1). By doing so, the pressing piece portion 56 rotates in the closing direction, and the pressing portion 56a presses the holding portion 53d of the first wing body 53 in the open state to be pulled toward the closing direction. Accordingly, when the first wing body 53 rotates about the rotational axis A1 as a central axis, the outer peripheral side portion 53A of the first wing body 53 moves to the indoor side (arrow C2), and the center The side part 53B moves toward the insertion tube 52 side. In this way, the 1st wing body 53 will be in a closed state.

In the case of operating from the open state to the closed state, as opposed to the case of operating from the closed state to the open state, the pressing part of the pressing piece part 56 according to the rotational movement of the pressing piece part 56 and the first wing body 53 . The position of 56a is shifted from the center side of the insertion tube 52 toward the outer peripheral side in the left-right direction X with respect to the first wing body 53 . However, the holding portion 53d is allowed to shift, so that the holding portion 56a can be continuously held.

The connecting piece portion 55 is pulled by the first wing body 53 to rotate, and the first shaft support portion 55a moves toward the interior (arrow C3). At the same time, the second shaft support portion 55b moves toward the outdoor side (arrow C4), and the center side portion 54B of the second wing body 54 rotates toward the outdoor side to enter a closed state (arrow C4). C5).

As described above, in the holding portion 53d, a second protrusion 53d2 protruding into the movable gap 53e is formed. When the operation portion 56c2 is moved from the open state to the closed state, the pressing portion 56a having the movable gap 53e moved can be fixed at a position beyond the second protruding portion 53d2. In this way, since the pressing piece portion 56 is fixed at the closed position, the first wing body 53, the connecting piece portion 55, and the second wing body 54 are also maintained in the closed state. Also, similarly to the case of changing from the closed state to the open state, the operator can obtain a clicking feeling in the vicinity when the pressing portion 56a that has moved inside the movable gap 53e crosses the second protruding portion 53d2. It can be confirmed by the sense of the hand that the fixation has been made securely.

In this state, since the end face 53f of the first wing body 53 and the end face 54c of the second wing body 54 oppose in a close state to block the insertion tube 52, the ventilation path R is closes Therefore, intrusion of dust, raindrops, etc. from the outdoors can be suppressed.

As described above, the pressing piece portion 56 has a first installation shaft portion 56b formed of an integral structure, a second installation shaft portion 56c, and a protrusion portion 56A having the pressing portion 56a. When this pressing part 56a directly presses the 1st wing body 53, it rotates the pressing piece part 56 compared with the case where another member is interposed or the pressing piece part 56 is comprised from several members. The force to move can be easily transmitted as a force for rotating the first wing body 53 . Therefore, it can be set as the ventilation register 51 which is easy to operate for an operator.

Moreover, compared with the case where the press piece part 56 which consists of such a plurality of members is provided, the number of parts can be reduced. Therefore, it can be set as the ventilation register 51 which is easy to manufacture and has a low cost. In a preferred embodiment, although the pressing piece portion 56 has an integral structure, it is clear that the pressing piece portion 56 of the present invention may be constituted by a plurality of members.

Variants:

In the second embodiment, an example is shown in which the first mounting shaft portion 56b and the second mounting shaft portion 56c have substantially the same length, and the pressing portion 56a is provided approximately at the center in the height direction Z. it was On the other hand, one of the mounting shaft portions 56b and 56c may be provided longer than the other, and the pressing portion 56a may be provided with a biased position between the upper side and the lower side.

In the second embodiment, an example is shown in which the pressing portion 56a has the protruding portion 56A protruding in a U-shape. On the other hand, you may provide the protrusion which consists of a shape protruding in the shape of a mountain, for example. In this case, what is necessary is just to make the front-end|tip part of the mountain shape linear so that the inside of the movable clearance gap 53e of the holding|maintenance part 53d which the holding|maintenance part 53d of the 1st blade body 53 has the press part 56a can displace smoothly. By doing in this way, it is possible to suppress a situation in which the tip of the protruding portion 56A is stuck in the holding portion 53d or the blade piece 53c and the inside of the movable gap 53e cannot be moved.

In the second embodiment, an example in which the first mounting shaft portion 56b and the second mounting shaft portion 56c of the pressing piece portion 56 are rotatably supported with respect to the outer frame portion 57a of the cover body 57 . was shown. On the other hand, the part on which the pressing piece part 56 is supported is not limited to the outer frame part 57a, for example, the 1st installation shaft part 56b is a part of the insertion tube 52 in the cover body 57. The upper side or the upper side of the indoor opening portion 52a of the insertion tube 52 may be pivotally supported so as to be able to rotate. Thereby, since the pressing piece part 56 can be made small, material cost can be made cheap.

(Third embodiment)

In this embodiment, it is not limited to the ventilation register of 1st Embodiment or 2nd Embodiment, A nanofilter is attached to the ventilation register of a well-known structure. The ventilation resistor of the present invention is characterized in that it includes a nanofilter, and any known structure of the ventilation resistor itself can be used. A third embodiment will be described below with reference to the drawings, but it should be understood that the present invention is not limited to the specific structure of this ventilation resistor. For example, it is applicable also to the thing of the structure which inserts a cylindrical pleated filter into an insertion cylinder like the ventilation register of 1st Embodiment or 2nd Embodiment. 20 shows a view in which the nanofilter is mounted on a known general ventilation resistor except for installing a backspace.

Because of the thin fibers of nanofilters, they look like paper, and in fact, there may be cases in which the pressure loss is large even when the filter media is laid flat on a ventilation register. Therefore, in a preferred embodiment, the nanofilter can be pleated. The pleat shape and size are not particularly limited. For example, the height of the peak of the pleats is about 5 to about 40 mm, preferably about 10 to about 30 mm, more preferably about 15 to about 25 mm (for example, 15 mm , 25 mm, etc.). The pitch of the pleats is also not particularly limited, and may be, for example, about 3 to about 10 mm (specifically, 8 mm, 6 mm, 4 mm, etc.). Pleated processing to the nanofilter can be formed by pleating a flat filter filter material with a known pleat processing machine (rotary pleat machine, recipe pleat machine, line pleat machine, etc.).

In addition to or instead of pleating the nanofilter, a backspace may be provided in the ventilation resistor of the present invention. The backspace is a space between the holding portion and the pre-filter, as shown in FIG. 20 . The pre-filter is a filter through which the gas supplied through the ventilation register passes before passing through the nano-filter (for example, filter PS-150 manufactured by Nippon Bairin Co., Ltd.), and typically the particle diameter collected by the nano-filter It is used for pre-collecting larger particles with a particle diameter of about 5 μm or more.

By providing the backspace, the pressure loss can be improved because, for example, air that has passed through the insertion tube can pass through the front surface of the pre-filter having a cross-sectional area larger than the cross-sectional area of the insertion tube (FIG. 20). In the backspace, the interval between the insertion passage and the pre-filter may be any interval within the range capable of improving the pressure loss. A person skilled in the art is skilled in the art that between the canister and the pre-filter in the backspace, so that the air passing through the canister having a circular cross section can pass through the wider face of the prefilter having a rectangular cross section having a cross section larger than that of the circular section of the canister. spacing can be appropriately determined. For example, the interval between the insertion tube and the pre-filter may be about 5 mm or more, but the present invention is not limited thereto. On the other hand, the interval between the insertion tube and the pre-filter means the distance between the outlet of the insertion tube and the pre-filter.

When the backspace does not exist, since the air that has passed through the insertion tube passes through the pre-filter and the nano-filter as it is, only the area corresponding to the cross-sectional area of the insertion tube of the nano-filter is ventilated. As a result, in the ventilation register not provided with the backspace, trapping marks were formed on the nanofilter in an area and shape corresponding to the cross-section of the insertion tube (not shown). On the other hand, by providing the backspace, the air passing through the canister passes through the front surface of the filter, and as a result, the collection efficiency and the pressure loss are improved. In addition, since the collecting area of the filter is spread from the portion corresponding to the cross section of the insertion tube to the whole, it is considered that the duration of the collecting performance is also extended.

In one embodiment, the ventilation resistor of the present invention collects 40% or more, preferably 60% or more, of fine particles having a particle diameter of 0.3 μm to 0.5 μm with respect to an airflow at a linear velocity of 2.5 m/s in the ventilation port, , more preferably 70% or more can be collected. Alternatively, the ventilation resistor of the present invention contains 40 to 90%, 60 to 90%, 70 to 90%, 40 to 80 of fine particles having a particle diameter of 0.3 μm to 0.5 μm with respect to an airflow having a linear velocity of 2.5 m/s in the ventilation port. %, 60-80%, or 70-80% can be collected.

In one embodiment, the ventilation resistor of the present invention collects 70% or more, preferably 75% or more, of fine particles having a particle diameter of 0.5 to 1 μm with respect to an airflow at a linear velocity of 2.5 m/sec in the ventilation port, More preferably, 80% or more can be collected, Especially preferably, 85% or more can be collected. Alternatively, the ventilation resistor of the present invention contains 70 to 95%, 80 to 95%, 85 to 95%, and 70 to 90% of fine particles having a particle diameter of 0.5 to 1 μm with respect to an airflow having a linear velocity of 2.5 m/sec in the ventilation port. , 80-90%, or 85-90% can be captured.

In one embodiment, the ventilation resistor of the present invention collects 85% or more of fine particles having a particle diameter of 1 to 2 μm with respect to an airflow at a linear velocity of 2.5 m/sec in the ventilation port, preferably 90% or more, More preferably, 93% or more can be collected.

In one embodiment, the ventilation resistor of the present invention can trap 95% or more of fine particles having a particle diameter of 2 to 5 μm, preferably 98% or more, with respect to an airflow with a linear velocity of 2.5 m/sec in the ventilation port. there is.

In one embodiment, the ventilation resistor of the present invention can trap almost 100% of fine particles having a particle diameter of 5 µm or more with respect to an airflow having a linear velocity of 2.5 m/sec in the ventilation port.

In one embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 100 mm, and the pressure loss coefficient may be 180 or less. In a preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 100 mm, and the pressure loss coefficient may be 120 or less. In a further preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 100 mm, and the pressure loss coefficient may be 80 or less. In a particularly preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 100 mm, and the pressure loss coefficient may be 50 or less.

In one embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 150 mm, and the pressure loss coefficient may be 120 or less. In a preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 150 mm, and the pressure loss coefficient may be 80 or less. In a more preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 150 mm, and the pressure loss coefficient may be 60 or less. In a particularly preferred embodiment, in the ventilation resistor of the present invention, the diameter of the ventilation port may be 150 mm, and the pressure loss coefficient may be 45 or less.

In the ventilation resistor of the present invention, the cross-sectional area of the nanofilter set in the case may be about 2.0 to about 2.7 times the cross-sectional area of the ventilation hole. On the other hand, the 'cross-sectional area of the nano-filter' is not the developed area of the pleated nano-filter, but the cross-sectional area of the case body in which the nano-filter is set.

In one embodiment, as shown in FIG. 21, you may provide by providing the filter system (case body) provided with a nano-filter and a pre-filter so that it may cover the existing indoor resistor. Accordingly, a high-performance filter can be easily installed in many existing buildings. In this case, the cross-sectional area of the nano-filter set in the case may be about 3.0 times to about 5.0 times the cross-sectional area of the ventilation hole. On the other hand, as shown in FIG. 21, the backspace in such a filter system refers to the distance from the insertion cylinder of the indoor register installed previously to the pre-filter of a filter system. The backspace of the filter system may be about 20 to about 60 mm, preferably about 30 to about 40 mm.

(Other embodiment)

In the above, preferred embodiments have been shown and described for ease of understanding of the present invention. Hereinafter, the present invention will be described based on examples, but the above description and the following examples are provided for the purpose of illustration only, and not for the purpose of limiting the present invention. Accordingly, the scope of the present invention is not limited to the embodiments specifically described herein nor to the examples, but is limited only by the claims.

Example

(Example 1: Review of pressure loss in ventilation resistors using nanofibers)

As ventilation resistors that are generally used, a conventional air supply resistor equipped with an electrostatic filter and an air supply resistor equipped with two types of nanofiber filters of the present invention, respectively, were set in a pressure loss measuring device, and the pressure loss was measured. The pressure loss is measured based on the measurement method described in Annex 1 of JIS C9603 (ventilation fan). As shown in FIG. 25, the pressure loss measuring device connects the measuring port (duct) and the ventilation resistor to measure so that there is no air leakage. The diameter of the duct, which is a measurement port connected to the ventilation resistor, is actually the same as the size of the ventilation hole to which the ventilation resistor is mounted. In this measurement, the diameter of the duct serving as the measuring hole is Ø100mm (100 pie). An appropriate orifice is selected according to the air volume. Rectification nets and blower plates are installed to equalize the wind speed in the air tank. The air volume is controlled by the power controller. When measuring, adjust the static pressure of the air tank to be the same as the static pressure when measuring the air volume of the ventilation resistor (so that the static pressure becomes 0), and then measure the air volume with a recorder (for example, a manometer manufactured by Okaya Seisakusho Co., Ltd.) reading the differential pressure between the air tank and the measuring pipe.

In the actual measurement, first, the air volume-static pressure curve in the state (state 1) in which the ventilation resistor to be measured is connected to the measurement port is obtained. Next, the air volume-static pressure curve in the state (state 2) where the ventilation resistor is removed from the measuring tool is calculated|required. Then, the pressure loss curve is calculated based on the difference between the air volume-static pressure curve in the state 1 and the air volume-static pressure curve in the second state. In the measurement, the static pressure is measured up to 100 Pa. On the other hand, in this specification, the pressure loss coefficient ζ is calculated by the following formula.

ζ=δP×((4.03×duct cross-sectional area)/air volume)^2

δP is the differential pressure recorded by the recorder.

The results are shown in FIG. 22 .

With respect to the conventional electrostatic filter, the pressure loss was measured by setting for two different types of case body designs ( FIGS. 22A and 22B ). Although it is the same electrostatic filter, it can be seen that B has less pressure loss than A due to the difference in case design (that is, when the same static pressure of 100 Pa is applied, B has more amount of permeated gas than A) .

Two types of nanofilters were set in the same case body as the case body design with little pressure loss (Fig. 22B). C1, C2, and C3 in Fig. 22 show that, for a nanofilter having a fiber diameter of about 125 nm and a pore diameter of about 10 μm (Nitto Denko Co., Ltd., Osaka, Japan), the pleat pitch was about 8 mm (C1) and about 6 mm (C2). ), about 4 mm (C3). D1, D2 and D3 in Fig. 22 show that, for a nanofilter having a fiber diameter of about 60 nm and a pore diameter of about 5 μm (Nitto Denko Co., Ltd., Osaka, Japan), the pleat pitch was about 8 mm (D1) and about 6 mm (D2). ), about 4 mm (D3). The height of the pleats is about 15mm for all of D1, D2, and D3.

It should be noted that there is a large difference in the collection efficiency between the ventilation resistors A and B and the ventilation resistors C1 to C3 and D1 to D3. That is, the ventilation resistors of A and B had a collection efficiency of only 46.3% of particles with a particle diameter of 0.5 to 1.0 μm, whereas the ventilation resistors of C1 to C3 and D1 to D3 were remarkably superior to that. For example, the collection efficiency of particles with a particle diameter of 0.3 μm also exceeded 70%. In C1 to C3 (fiber diameter about 125 nm, pore diameter 10 μm) and D1 to D3 (fiber diameter about 60 nm, pore diameter about 5 μm), D1 to D3 had better collection efficiency.

Nevertheless, the pressure loss of B and the pressure loss of C1 and D1 did not change to that extent, and the pressure loss of C2, C3, D2 and D3 even exceeded the pressure loss of B. That is, the pressure loss coefficient of the conventional product A was 178.8 and the pressure loss coefficient of B was 45.55, whereas the pressure loss coefficient of C1 was 54.5, C2 37.39, C3 29.98, D1 42.76, D2 34.9, D3, respectively. was 26.12.

These results are very unexpected in the art, and the data of Fig. 22 clearly showed the possibility of application of the nanofilter to a ventilation register, which is considered to be unusable for a ventilation register for natural air supply. Importantly, this trend did not change with the air volume and appeared consistently at any air volume. Although it is also required to cope with a widely fluctuating air volume, the possibility of application of the nanofilter to the ventilation register of the third type ventilation system was demonstrated.

In addition, please note that the tendency to improve the pressure loss is consistently observed by reducing the pitch of the pleats to about 8 mm, about 6 mm, and about 4 mm.

(Example 2: Review of pressure loss and collection efficiency between the nano filter and other filters)

For the nanofilter with a fiber diameter of about 60 nm and a hole diameter of about 5 μm used in Example 1, the pleat pitch was about 4 mm and the peak height was about 15 mm, and a conventional electrostatic filter (pleated processing) set in the same case body. untreated) and radially pleated microfilters (Filter VB-YA100PM manufactured by Panasonic Ecosystems Ventech Co., Ltd.: fiber diameter of about 15 μm to about 46 μm), pressure loss and time-series changes in collection efficiency were confirmed.

23A is a nanofilter ventilation resistor of the present invention (A1 is the initial value, A2 is after 40 hours), B is a conventional microfilter (B1 is the initial value, B2 is after 30 hours), C is a conventional of the electrostatic filter (C1 is the initial value, C2 is after 30 hours). 23A shows a time series change in pressure loss, and FIG. 23B shows a comparison of collection efficiencies.

The pressure loss was measured with a digital manometer (manometer (F-213) manufactured by Tsukubarika Seiki Co., Ltd.) by measuring the differential pressure between upstream and downstream of the filter when air was passed through the filter unit as the measurement object at an air flow rate of 2.5 m/sec.

In the nanofilter ventilation resistor of the present invention, the dust collection efficiency of 0.3~0.5㎛ exceeded 70%, and it was found that it could be afforded for commercial use as it draws a gentle curve even when looking at the passage of time of pressure loss. The micro filter has a larger pressure loss than the electrostatic filter, so it is not suitable for the ventilation register of the natural air supply.

[Table 1]

On the other hand, with respect to the initial value B1 of the microfilter, it is considered that leakage has occurred between the case body and the filter. In addition, it is considered that the collection efficiency is improved because the leakage between the microfiber fibers is improved as the particles or the like adhere to the microfiber fibers with the lapse of time. In addition, the microfilter is considered to have a short lifespan because the progress of clogging by particles adhering to the microfiber fibers over time is faster than that of other filters.

(Example 3: Review of mountain height)

As a result of the research and development of the present inventors, it was found that the conditions of pleat processing are important to improve the pressure loss of the nanofilter.

In this embodiment, the pressure loss was measured in the nanofilter with a pitch of about 4 mm and a height of about 15 mm, and a nano filter with a pitch of about 4 mm and a height of about 25 mm.

The results are shown in FIG. 24 . A denotes a ventilation resistor with a pitch of about 4 mm, a height of about 15 mm, and a backspace of about 5 mm, and B denotes a ventilation resistor with a pitch of about 4 mm, a height of about 25 mm and a backspace of about 5 mm.

As can be seen from the results of A and B, it was found that the higher the mountain height, the larger the developed area of the nanofilter was obtained, and the pressure loss was improved.

(Example 4: Durability)

A nanofilter having a fiber diameter of about 60 nm and a pore diameter of about 5 μm was actually installed at the inventor’s house, and the pressure loss was measured after using it for one month. As a result, it was found that the air flow rate decreased by about 6% due to clogging.

The nanofilter was washed with water, and the pressure loss was measured again, and almost returned to the initial value.

1: Ventilation register
2: vent
3: Insertion tube
3a: indoor open end
3b: outdoor side open end
3c: ventilation room
4: face part
5: inner wall
6: Outward Flange
6a: outer frame
7: Reputation
7a: handle part
7b: rectification dome part
8: cylindrical pleated filter unit
8a: pleated part
8b: indoor open end
8c: outdoor side open end
9: Retention Department
9a: seal
10a: seal part
10b: seal part
11: ventilation gap
11a: air
12: support
13: pre-filter
14: Ventilation register (modified example)
15: Ventilation resistor (modified example)
S: screw fixing part
51: ventilation register
51A: opening and closing structure
52: insertion tube
52a: indoor opening
53: first wing body
53A: outer peripheral side
53B: central side
53a: fixed part
53b: fixed part
53c: wing piece
53d: holding department
53d1: first protrusion
53d2: second protrusion
53e: movable clearance
53f: end face
54: second wing body
54A: outer peripheral side
54B: central side

Claims (14)

A ventilation register used in a natural air supply, comprising:
Insertion passage to be installed by inserting into the ventilation hole of the building;
a face portion capable of moving forward and backward with respect to the indoor opening of the insertion tube and having a handle portion on the indoor side;
a pre-filter through which the gas that has passed through the insertion tube passes;
A filter material made of nano-filter through which the gas that has passed through the pre-filter passes is provided;
The nano-filter in the filter material made of the nano-filter is a filter with a thickness of 3-20 μm composed of nanofibers having a fiber diameter of 1 to 250 nm,
With a pitch of 3 to 10 mm, and pleats with a peak height of 5 to 40 mm,
It is to collect more than 60% of particles with a particle diameter of 0.3 to 0.5 μm with respect to an airflow with a linear velocity of 2.5 m/sec in the vent, not an electrostatic filter,
The ventilation resistor is for a ventilation port with a diameter of 100 mm, and the pressure loss coefficient of the ventilation resistor is 180 or less. The method of claim 1,
A ventilation resistor having a pressure loss coefficient of 120 or less of the ventilation resistor. 3. The method of claim 1 or 2,
A ventilation register in which the nanofilter-made filter medium collects 70% or more of fine particles having a particle diameter of 0.3 to 0.5 µm with respect to an airflow having a linear velocity of 2.5 m/sec in the ventilation port. The method of claim 1,
The nanofiber is a ventilation resistor having a fiber diameter of 50 ~ 150nm. The method of claim 1,
The filter material made of the nano filter is a ventilation resistor having pleats with a pitch of 4 to 8 mm, and a peak height of 15 to 25 mm. The method of claim 1,
The thickness of the nano-filter-made filter is 3-10㎛ ventilation resistor. The method of claim 1,
A ventilation register having a backspace between the pre-filter and the insertion passage. 8. The method of claim 7,
The backspace is a ventilation resistor of 5 mm or more. The method of claim 1,
The cross-sectional area of the filter medium made of the nano-filter is 2.0 to 2.7 times the cross-sectional area of the ventilation port. A ventilation register used in a natural air supply, comprising:
Insertion passage to be installed by inserting into the ventilation hole of the building;
a face portion capable of moving forward and backward with respect to the indoor opening of the insertion tube and having a handle portion on the indoor side;
a pre-filter through which the gas that has passed through the insertion tube passes;
A filter material made of nano-filter through which the gas that has passed through the pre-filter passes is provided;
The nano-filter in the filter material made of the nano-filter is a filter with a thickness of 3-20 μm composed of nanofibers having a fiber diameter of 1 to 250 nm,
With a pitch of 3 to 10 mm, and pleats with a peak height of 5 to 40 mm,
It is to collect more than 60% of particles with a particle diameter of 0.3 to 0.5 μm with respect to an airflow with a linear velocity of 2.5 m/sec in the vent, not an electrostatic filter,
The ventilation register is for a ventilation port with a diameter of 150 mm, and the pressure loss coefficient of the ventilation resistor is 120 or less. 11. The method of claim 10,
A ventilation resistor having a pressure loss coefficient of 80 or less of the ventilation resistor. 12. The method according to claim 10 or 11,
The cross-sectional area of the filter medium made of the nano-filter is 2.0 to 2.7 times the cross-sectional area of the ventilation port. A filter system for installation in a ventilation register having an insertion tube inserted into a ventilation port of a building used for a natural air supply, and movable forward and backward with respect to an indoor opening of the insertion tube, and having a face portion having a handle on the indoor side As such, the filter system includes a nano-filter-made filter medium and a pre-filter,
The nano filter,
It is a filter with a thickness of 3 to 20 μm, composed of nanofibers with a fiber diameter of 1 to 250 nm.
It has pleats with a pitch of 3 to 10 mm, and a mountain height of 5 to 40 mm, and is not an electrostatic filter,
The filter system is
A filter system that collects more than 60% of particles with a particle diameter of 0.3 to 0.5 μm with respect to an airflow with a linear velocity of 2.5 m/sec in the vent. 14. The method of claim 13,
The nanofiber has a fiber diameter of 50 to 150 nm, the nano filter has a pitch of 4 to 8 mm, and pleats having a mountain height of 15 to 25 mm, and the filter system has an air flow of 2.5 m/sec in a ventilator. A filter system that captures 70% or more of particulates with a particle diameter of 0.3 to 0.5 μm.

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