JP7039755B1 - Air distribution panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air circulation panel capable of easily connecting a roof panel provided with an air circulation mechanism in a building for circulating air in the entire building. SOLUTION: A panel unit is composed of a vertically long heat insulating board having heat insulating properties, a rafter made of a rod-shaped member having the same length as the heat insulating board, and a field board made of a flat plate constituting the roof of a building, and the rafters are formed. Consists of a hat-type rafter with a convex flange on both the left and right sides for mounting the heat-insulating board, and a joint rafter with a joint part that can be closely joined to the hat-type rafter. Hat-type rafters are made by placing heat insulating boards on the collar and arranging them side by side alternately in the horizontal direction. Joint rafters are installed on either the left or right end of the panel unit, and the field board is insulated. By connecting to the upper surface of the rising surface of the board and the upper surface of the hat-shaped rafters, an air flow layer is formed in the panel unit. [Selection diagram] Fig. 1

Description

The present invention relates to a panel to be installed on the roof of a building, and makes it possible to install an air flow mechanism in the building that circulates air throughout the building by passing air inside the roof panel of the building, and easily connects the panels. It relates to an air flow panel for forming a roof panel that can be mounted.

Conventionally, cooling devices such as coolers and heating devices such as stoves and gas heaters have been widely used as equipment used for air conditioning equipment in buildings. In recent years, equipment installed in buildings such as underfloor heating equipment has become widespread, and there is also a system that comprehensively and automatically manages such air conditioning to keep the temperature and humidity inside the building constant. Various systems that have been developed and pursue the comfort and economy of living spaces that centrally manage the air conditioning in buildings are widespread.

In recent years, technology related to air-conditioning equipment in energy-saving buildings that is environmentally friendly is required, and in recent years, electricity, etc. that uses the heat of sunlight and the natural wind without using the above-mentioned electronic devices. Environment-friendly air conditioning that does not use energy has been developed and used.

The applicant of the present invention is the patentee of Japanese Patent No. 6322601 (Japanese Patent Laid-Open No. 2016-223255). Here, it is an air flow panel that is a roof panel used for the air flow mechanism in a building, and consists of a rafter, a heat insulating board, and a field board, and a single heat insulating board with a pair of rafters rising on both sides. A technology to form an air flow layer through which air flows between the rising edge of the heat insulating board and the field board by fixing and fixing it to the upper end of the rafters that are flush with the rising top of the field board. Is disclosed.

According to this technique, it is possible to form an air flow panel having an air flow layer. However, since the roofs of buildings come in various sizes and shapes, it may be necessary to process air flow panels on site, and some roofs require the panels to be connected and installed, making them easily airtight. There is a problem that a structure that maintains the properties is not secured, and it takes time to construct a roof in which the panels are securely connected to each other.

When constructing a roof with an air distribution layer, an air distribution panel is created in advance as a unit at a location other than the site, and the unit is simply brought to the site and installed on the roof to create an air distribution layer. It is possible to easily and surely construct the roof to have, shortening the construction period, reducing work mistakes, accidents, etc. It has been desired to develop an air flow panel for forming a roof panel, which enables such panels to be easily connected to each other.

JP-A-2016-223255

In order to solve the above problems, the present invention constitutes a panel installed on the roof of a building, and constitutes an in-building air flow mechanism that circulates air throughout the building by passing air through the inside of the roof panel of the building. Provided is an air flow panel for constituting a roof panel, which enables the panel to be easily connected and mounted.

An air flow panel that can be connected to a roof provided with an air flow layer for allowing air to flow in an internally formed through space according to the present invention in order to achieve the above object rises at both ends of the upper surface in the longitudinal direction. A vertically long heat insulating board consisting of one or more heat insulating boards erected in parallel, a plurality of rafters made of rod-shaped members having the same length as the heat insulating board, and a field board made of flat plates constituting the roof of the building. The rafters constitute a panel unit consisting of a hat-shaped rafter consisting of inverted T-shaped cross-sections in which the collars for mounting the heat insulating board are convex on both the left and right sides, and the rafters are convex on one of the left and right sides. It is composed of a joint rafter having a collar made of and having a concave joint portion that can be closely joined to the hat-shaped rafters on the other side, and the heat insulating board and the hat-shaped rafters are made of the heat insulating board. It is placed on the flange and arranged side by side alternately in the horizontal direction, and the upper surface of the rising surface of the heat insulating board and the upper surface of the hat-shaped rafters are formed flush with each other, and further, the left and right sides of the panel unit are formed. A rafter for joints is continuously provided at one end, and the joint portion enables the rafters to hold and fix the heat insulating board while closely contacting the air flow panel to the left and right. One of the lower surfaces of the joint rafters is cut and formed in the same shape as the flange of the hat-shaped rafters, and the field board is connected to the rising upper surface of the heat insulating board and the upper surface of the hat-shaped rafters. As a result, an air flow layer is formed in the panel unit.

In addition , the hat-shaped rafters are joints where the collar and the joint are joined in order to securely fix the air flow panels that are connected to the left and right and prevent leakage of water or air. By applying a sealing agent to the rafters, it is also sealed and joined to the rafters for joints.

Since the present invention has the configuration as described in detail above, it has the following effects.
1. 1. Since the rafters are made into a hat type, it is possible to stably fix the heat insulating board. Further, since the rafters for joints are provided at either the left or right end of the panel unit, the panels can be connected to the left and right.
2. 2. Since one of the lower surfaces of the joint rafters has the same shape as the collar of the hat-shaped rafters, the panels can be connected without gaps.
3. 3. Since the sealing agent is applied to the portion where the flange portion and the joint portion are in close contact with each other, the air flow panels can be reliably sealed and joined to prevent leakage of water or air.

Hereinafter, the air flow panel according to the present invention will be described in detail based on the examples shown in the drawings.
FIG. 1 is a perspective view of an air flow panel according to the present invention, and FIG. 2 is a cross-sectional view of the air flow panel. FIG. 3 is a perspective view of an air flow panel installed on the roof.

As shown in FIGS. 1 and 2, the air flow panel 1 of the present invention is a roof panel that can be connected to a roof and is installed on the roof of a building composed of a heat insulating board 10, a hanging tree 20, and a field board 30. An air flow layer a for circulating air is formed inside the panel, and the temperature inside the building is adjusted by circulating air through the air flow layer a. Is.

The heat insulating board 10 is a member having heat insulating properties arranged inside the roof of the building of the air flow panel 1, and is a vertically long member having a rectangular parallelepiped shape having the same length as the rafters 20 as shown in FIGS. 1 and 2. Is. A rising edge 12 is installed on the heat insulating board 10. As shown in FIG. 2, the rise 12 is erected in parallel on both ends of the upper surface of the heat insulating board 10 in the longitudinal direction.

The rise 12 is erected on the heat insulating board 10 so that when the rafters 20 sandwich and fix the heat insulating board 10, the height is aligned with the upper end of the rafters 20. With this structure, when the field board 30 is fixed to the rafters 20, the rising edge 12 of the heat insulating board 10 comes into close contact with the field board 30, and the heat insulating property and the sealing property of the air flow layer a formed by the rising 12 are ensured. It becomes possible to do.

The rafter 20 is a hut structure member, which is a member that serves as a frame of the air flow panel 1, and is a member made of a rod-shaped member having the same length as the heat insulating board 10 as shown in FIGS. 1 and 2. In this embodiment, the rafters 20 are members that constitute a hut structure and are members that form the framework of the air flow panel 1, and are composed of prisms having an inverted T-shaped cross section as shown in FIG. The rafter 20 uses wood such as pine or cedar as its material, and is formed by processing the wood into an elongated shape, but the material is not limited to these.

The field board 30 is a member for constituting the roof of a building, and is made of a flat plate as shown in FIGS. 1 and 2. The rising 12 of the heat insulating board 10 and the rafter 20 are joined to the field board 30 while the rafters 20 are alternately and continuously arranged side by side in a state where the heat insulating board 10 is sandwiched and fixed. As a result, a panel unit P capable of joining a plurality of panels is configured. The field board 30 is made of wood plywood in this embodiment, but is not limited thereto.

In this embodiment, the rafters 20 are configured to include either the hat-shaped rafters 22 or the joint rafters 24. The hat-type rafter 22 is a member for mounting and stably holding the heat insulating board 10, and as shown in FIG. 2, the flange portion T is projected on both the left and right sides of the lower surface of the rafter. It is composed of T-shaped stripes.

Further, as shown in FIG. 2, the rafters 24 for joints have a configuration in which a flange portion T is convexly provided on either the left or right side of the lower surface of the rafters. Further, it has a structure in which the joint portion J is cut on the other side. The joint portion J is a member having a concave shape for fitting the flange portion T of the hat-type rafters 22 so that the hat-type rafters 22 and the joint rafters 24 can be closely joined to each other. The side surface of the panel unit P on which the hat-shaped rafters 22 are provided and the side surface on the opposite side of which the joint rafters 24 are provided are fitted and closely contacted, thereby making it possible to closely connect the panel unit P. ..

Next, the basic structure of the air flow panel 1 will be described. In this embodiment, as shown in FIGS. 1 and 2, the heat insulating board 10 and the hat-type rafters 22 are arranged alternately in the horizontal direction by mounting the heat-insulating board 10 on the flange portion T of the hat-type rafters 22. It is a structure that is installed side by side. That is, the side surface of one hat-type rafter 22 is connected to and adheres to one side surface of the heat insulating board 10, and the side surface of the other hat-shaped rafter 22 facing each other is connected to and adheres to the other side surface of the heat insulating board 10. By doing so, the heat insulating board 10 is sandwiched and fixed. By repeating this sandwiching structure a plurality of times, one panel unit P is formed. At this time, the hat-shaped rafters 22 are configured to mount the heat insulating board 10 on the collar portion T. This makes it possible to prevent the heat insulating board 10 from shifting up and down and fix the heat insulating board 10 more firmly.

Further, as shown in FIG. 1, a joint rafter 24 is continuously provided at one of the left and right ends of the panel unit P in place of the hat-type rafter 22. With this configuration, the panel unit P can be closely connected to the left and right. In this embodiment, the rafters 24 for joints are installed only at one of the left and right ends of the panel unit P, but the configuration is not limited to this, and for example, any of the left and right ends of the panel unit. Also, a hat-type rafter 22 is installed, or joint rafters 24 are installed at both the left and right ends of the panel unit, and these panel units are appropriately combined so that the hat-type rafter 22 and the joint rafter 24 are joined to the roof. Of course, it is also possible to install it in.

Further, in this embodiment, as shown in FIGS. 1 and 2, the upper surface of the rising edge 12 of the heat insulating board 10 and the upper surface of the hat-shaped rafters 22 are formed so as to be flush with each other. Further, the field board 30 is connected to the upper surface of the rising edge 12 of the heat insulating board and the upper surface of the hat-shaped rafters 22 and the joint rafters 24.

With this structure, the heat insulating board 10 is integrated with the field board 30 via a pair of hat-type rafters 22 (or hat-type rafters 22 and joint rafters 24), and can be firmly fixed. Further, as shown in FIG. 2, it is possible to form an air flow layer a for circulating air between the surface of the heat insulating board 10 and the rising edge 12 of the heat insulating board 10 and the field board 30. Since the heat insulating board 10 is mounted on the flange portion T of the hat-shaped rafters 22 or the joint rafters 24, the heat insulating board 10 is sandwiched and fixed by the flange portion T and the field plate 30, and airtightness is ensured.

With the above configuration, as shown in FIG. 3, it is possible to construct a roof panel having an excellent heat insulating effect, and for a roof having an air flow layer a that suppresses the occurrence of air leakage. It became possible to construct a panel, and it became possible to promote air circulation in the building and perform heating and cooling.

The air in the internal space of the air flow layer a of the air flow panel 1 installed on the roof of the building does not move in a stagnant state in a stagnant state, but the field board 30 side. When sunlight is applied to the air, the air in the internal space is heated, an updraft is generated inside the air flow layer a, and an air flow is generated from the lower part to the upper part. Further, by simultaneously using the outer wall panel (not shown) having the air flow layer a used for the outer wall, an updraft is generated also in the air flow layer a of the outer wall. This updraft is the mechanism that drives the air flow in the building.

The air flow layer a may be configured to have a width that causes an updraft when heated, but the width should be within 24 mm in order to prevent the raised air from causing vortex retention inside or backflowing. It is desirable to have. Therefore, the rise 12 of the heat insulating board 10 is formed at a height of 24 mm in this embodiment, but is not limited to this value.

Further, in this embodiment, the heat insulating board 10 is coated with a vinyl-based material on the surface forming the air flow layer a. With this configuration, it is possible to obtain a higher heat insulating effect on the roof.

In this embodiment, the heat insulating board 10 can be formed of a resin such as styrofoam, polyurethane resin, highly foamed polyethylene, and foamed glass. In this embodiment, styrofoam is used as the material of the heat insulating board 10, but the present invention is not limited to this, and polyurethane resin, highly foamed polyethylene, and foamed glass can be appropriately selected and used.

As described above, the air flow panel 1 serving as the roof panel according to the present invention is configured such that the heat insulating boards 10 and the rafters 20 are alternately and continuously arranged so that the rafters 20 mount and sandwich the heat insulating boards 10 respectively. It has become possible to construct a roof panel in which a plurality of parallel air flow layers a are formed, and it has become possible to construct a roof panel unit P corresponding to roofs of all sizes and shapes.

In the joint portion J of the air flow panel 1 according to the present invention, as shown in FIGS. 1 and 2, one of the lower surfaces of the joint rafters J is cut and formed into the same shape as the flange portion T of the hat-shaped rafters 22. It is a composition consisting of. With this configuration, the flange T of the hat-type rafter 22 and the notch on the lower surface of the joint rafter J are tightly joined, and the panel unit P constituting the air flow panel 1 can be connected to the left and right. It became.

Further, as shown in FIG. 3, the hat-shaped rafters 22 constituting the air flow panel 1 according to the present invention are jointed by applying a sealing agent to the joint portion S where the flange portion T and the joint portion are joined. It is configured to be connected to the rafters 24. When connecting the panel units P of the air flow panel 1 to each other, if they are simply packed and lined up and fixed, water or air may leak from the gaps that are slightly created, and the air flow is reliable. Not only was it impossible to control the room temperature, but there was also the risk of rain leaks and the like. With the above configuration, the panel units P of the air flow panel 1 connected to the left and right are securely fixed to each other, and it is possible to prevent leakage of water or air gaps.

By making the air flow panel 1 according to the present invention have the above configuration, in order to construct a roof having an air flow layer a, the air flow panel 1 is manufactured in advance as a unit at a place different from the site such as a factory in advance. By simply bringing the panel unit P to the site and installing it on the roof, it is possible to easily and surely construct a roof with an air distribution layer a, shortening the construction period, reducing work mistakes, accidents, etc. It will be realized.

Perspective view of the air flow panel according to the present invention Cross section of air flow panel Perspective view of the air flow panel installed on the roof

1 Air flow panel 10 Insulation board 12 Rise 20 Rafters 22 Hat type rafters 24 Rafters for joints 30 Field board a Air flow layer J Joint part P panel unit S Joint part T collar part

Claims (2)

An air flow panel (1) that can be connected to a roof provided with an air flow layer (a) for circulating air in the penetrating space formed inside.
A vertically long heat insulating board (10) having heat insulating properties with rising surfaces (12) erected in parallel at both ends of the upper surface in the longitudinal direction, and a plurality of rafters (20) made of rod-shaped members having the same length as the heat insulating board. ), A field board (30) made of flat plates that make up the roof of a building, and a panel unit (P) made of.
The rafters (20) are a hat-shaped rafter (22) having an inverted T-shaped cross section in which a flange portion (T) for mounting the heat insulating board (10) is projected on both the left and right sides, and a hat-shaped rafter (22) that is convex on one side. It consists of a rafter for joints (24) having a flange portion (T) made of a mold and having a joint portion (J) made of a concave shape that can be tightly joined to the hat-shaped rafters on the other side.
The heat insulating board (10) and the hat-shaped rafters (22) are arranged side by side alternately and continuously in the horizontal direction by mounting the heat insulating board on the flange portion, and the rising of the heat insulating board (12). The upper surface of the rafter and the upper surface of the hat-shaped rafter are formed flush with each other, and further, a joint rafter (24) is continuously provided at one of the left and right ends of the panel unit (P).
One of the lower surfaces of the joint rafters is the hat-shaped rafters so that the joint portion enables the rafters to hold and fix the heat insulating board while closely adhering the air flow panels to the left and right. It is formed by cutting into the same shape as the collar part of
The field plate (30) is connected to the upper surface of the rising surface (12) of the heat insulating board and the upper surface of the hat-shaped rafters, whereby an air flow layer is formed in the panel unit. Air flow panel. The hat-shaped rafters have a joint portion (S) in which the flange portion and the joint portion are joined in order to securely fix the air flow panels connected to the left and right and prevent leakage of water or air. The air flow panel according to claim 1 , wherein the air flow panel is hermetically joined to the rafters for joints by applying a sealing agent to the rafters.

Images