JP2010047971A - Forced deaerating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a forced deaerating device capable of surely preventing the bulge of a waterproofing layer by forcedly discharging a gas between a waterproofing foundation and the waterproofing layer only by an installation on the waterproofing layer. <P>SOLUTION: The forced deaerating device discharges the gas between the waterproofing foundation 5 and the waterproofing layer 2 through a deaerating cylinder 3 projected towards an upper section from the waterproofing layer 2. The forced deaerating device includes a discharging cylinder 14 installed on the waterproofing layer 2 so as to surround the whole of the deaerating cylinder 3. The forced deaerating device includes an air blower 4 sucking the gas between the waterproofing foundation 5 and the waterproofing layer 2 into the discharging cylinder 14 through the deaerating cylinder 3 in the discharging cylinder 14 and discharging the gas to the outside. The forced deaerating device includes solar cells fitted to the discharging cylinder 14 as a power supply for driving the air blower 4. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a forced deaeration device for forcibly degassing a gas between a waterproof layer and a waterproof base through decylinder.

  Conventionally, a waterproof layer made of a waterproof sheet or the like is formed on a waterproof base made of concrete slab or the like as a waterproof measure on the roof of a building or the like. This waterproof layer may be formed directly on the waterproof base or may be formed via a ventilation layer. The former is referred to as a close contact method, and the latter is referred to as an insulation method.

By the way, in the above waterproof structure, when the moisture of the waterproof base after curing evaporates, or when the water or solvent between the waterproof base and the waterproof layer evaporates, water vapor is generated and the waterproof layer on the waterproof base is There may be a “bulge” that bulges upward. In order to prevent such blistering, conventionally, for example, as shown in Patent Document 1, a decylinder installed directly on a waterproof base or through a ventilation layer is used. In this decylinder, the space formed between the waterproof base and the waterproof layer communicates with the space on the waterproof layer, thereby degassing the gas between the waterproof base and the waterproof layer.
JP-A-2005-207168

  However, since the decylinder discharges the gas on the waterproof base by natural convection, sufficient deaeration cannot be performed and the blistering may occur.

  The present invention has been made in view of the above-mentioned conventional problems, and by simply installing on the waterproof layer, the gas between the waterproof base and the waterproof layer can be forcibly discharged to ensure the swelling of the waterproof layer. It is an object of the present invention to provide a forced deaeration device that can be prevented and saves the trouble of wiring work during battery replacement or installation.

  In order to solve the above problems, a forced deaeration device according to claim 1 of the present invention exhausts gas between the waterproof base 5 and the waterproof layer 2 through the decylinder 3 protruding upward from the waterproof layer 2. An exhaust cylinder 14 installed on the waterproof layer 2 so as to surround the entire decylinder 3, and between the waterproof base 5 and the waterproof layer 2 through the decylinder 3 in the exhaust cylinder 14. It is characterized by comprising a blower 4 that sucks the gas into the exhaust tube 14 and discharges it to the outside, and a solar cell provided in the exhaust tube 14 that serves as a driving power source for the blower 4.

  The forced deaerator according to claim 2 is the forced deaerator according to claim 1, wherein the exhaust tube 14 is formed in a vertical tube shape opening downward, and the solar cell 15 and the blower 4 are provided at an upper end portion of the exhaust tube 14. It is characterized by that.

  In the invention according to claim 1, by installing the exhaust pipe on the waterproof layer so as to surround the whole of the cylinder removal, the inside of the exhaust pipe can be communicated between the waterproof base and the waterproof layer through the cylinder removal. If the blower is driven in this state, the gas between the waterproof base and the waterproof layer can be forcibly discharged through the decylinder and the exhaust tube, thereby reliably preventing the waterproof layer from being swollen. In addition, since the power supply of the blower is constituted by a solar battery, it is possible to save the trouble of wiring work or the like during battery replacement or installation.

  In addition, in the invention according to claim 2, in addition to the effect of the invention according to claim 1, the forced degassing device is provided by providing a solar cell and a blower at the upper end of the vertical cylindrical exhaust tube that opens downward. It can be made compact, and the forced deaeration device in the installed state can be made difficult to disturb the person using the rooftop or the veranda.

  Hereinafter, an example of an embodiment of the present invention will be described with reference to the accompanying drawings. As shown in FIG. 1, the forced deaerator 1 of the present example is installed on the waterproof layer 2 so as to cover the decylinder 3 protruding upward from the waterproof layer 2.

  The waterproof layer 2 is formed on the waterproof base 5 via the ventilation layer 6, that is, in FIG. 1, the forced deaeration device 1 is waterproofed by an insulating method in which the waterproof layer 2 and the waterproof base 5 are insulated by the ventilation layer 6. Is used.

  The waterproof base 5 is made of a concrete slab constituting a roof top of a building such as a building or a house or a floor base of a veranda. The waterproof layer 2 is made of FRP or a vinyl chloride sheet, and the ventilation layer 6 is made of a ventilation sheet such as a rubber sheet having air permeability provided between the waterproof base 5 and the waterproof layer 2.

  The waterproof base 5, the waterproof layer 2, and the ventilation layer 6 are not limited to the above. For example, the ventilation layer 6 may be a synthetic resin foam sheet or a nonwoven fabric sheet, and the ventilation layer 6 may be formed integrally with the waterproof layer 2. In addition, a ventilation tape is applied on the waterproof base 5 and the waterproof layer 2 is stretched thereon, or a ventilation groove is formed on the upper surface of the waterproof base 5 to ensure air permeability between the waterproof base 5 and the waterproof layer 2. Also good.

  The decylinder 3 is installed at an appropriate location on the air-permeable layer 6 and includes an inner cylinder 7 that opens up and down and a covered cylindrical outer cylinder 8 that opens downward.

  A flange portion 10 protruding outward is formed at the lower end of the inner cylinder 7. By installing the flange portion 10 directly on the ventilation layer 6, the decylinder 3 is installed on the ventilation layer 6. In this installed state, the inner cylinder 7 protruding upward from the flange portion 10 protrudes above the waterproof layer 2 through an opening 11 penetrating vertically formed in the waterproof layer 2.

  The outer cylinder 8 is put on the upper part of the inner cylinder 7, and is attached to the inner cylinder 7 in this state. A ventilation gap communicating between the lid 8a of the outer cylinder 8 and the upper edge of the inner cylinder 7 and between the peripheral wall 8b of the outer cylinder 8 and the peripheral wall of the inner cylinder 7 12 and 13 are formed.

  The inside of the inner cylinder 7 communicates with the outside of the decylinder 3 through the ventilation gaps 12 and 13, and the lower end opening of the inner cylinder 7 communicates with the ventilation layer 6. Thereby, the air containing water vapor in the ventilation layer 6 passes through the inner cylinder 7 and the ventilation gaps 12 and 13 in order by natural convection, and the lower edge of the peripheral wall 8b of the outer cylinder 8 and the peripheral wall of the inner cylinder 7 Is discharged downward from the opening 24 between the two.

  The forced deaeration device 1 is installed directly on the waterproof layer 2 and surrounds the entire decylinder 3 projecting upward from the waterproof layer 2, and the sun attached to the upper end of the exhaust tube 14. The battery-equipped blower 18 is provided.

  The exhaust cylinder 14 is formed in a vertical cylindrical shape having a circular shape in a plan view that opens up and down, and its diameter is substantially the same in the vertical direction. The exhaust cylinder 14 is formed of a transparent member such as acrylic, so that the inside of the exhaust cylinder 14 can be confirmed from the outside, and the decylinder 3 can be easily arranged at the center of the exhaust cylinder 14.

  A flange portion 16 that protrudes outward is formed at the lower end portion of the exhaust tube 14. The flange 16 is formed integrally with the exhaust tube 14 and is made of the same transparent member as the exhaust tube 14. In order to install the forced deaeration device 1 on the waterproof layer 2, the flange portion 16 is placed on the waterproof layer 2, and the flange portion 16 is fixed to the waterproof layer 2 using a caulking material. Thus, by installing the forced deaeration device 1 using a caulking material, the existing waterproof layer 2 is not damaged. In addition, the collar part 16 may be fixed to the waterproof layer 2 or the waterproof base 5 with a fixing tool such as a bolt.

  The solar cell-equipped blower 18 includes a blower 4, a solar cell 15 that serves as a power source for the blower 4, and a case 20 that houses the solar cell 15.

  The upper edge of the exhaust tube 14 is bonded to the center of the lower surface of the case 20 in an airtight state via a sealing material or the like (not shown), whereby the solar cell-equipped blower 18 is attached to the exhaust tube 14. The case 20 constitutes a lid that closes the upper end of the exhaust tube 14.

  An insertion tube portion 19 that protrudes downward is formed at the center of the lower surface of the case 20. The insertion cylinder portion 19 is inserted into the exhaust cylinder 14 from the upper end opening of the exhaust cylinder 14 and communicates with the exhaust cylinder 14.

  The fan 4 a of the blower 4 described above is disposed in the insertion cylinder portion 19, and the fan 4 a is located below the solar cell 15 housed in the case 20. A motor 4b for driving the fan 4a is built in the case 20, and the fan 4 is constituted by the motor 4b and the fan 4a.

  The outer peripheral part of the case 20 protrudes outward from the peripheral wall part of the exhaust tube 14. An exhaust hole 21 is formed in the lower part of the outer peripheral surface of the case 20 over substantially the entire circumference. The exhaust hole 21 communicates with the upper end opening of the insertion cylinder part 19 through a flow path 22 formed in the case 20, and exhausts air in the exhaust cylinder 14 through the flow path 22 and the space in the insertion cylinder part 19. An exhaust flow path is configured.

  A window portion 23 made of a translucent member such as acrylic is provided at the center of the upper surface of the case 20, and the solar cell 15 described above is disposed below the window portion 23. The solar cell 15 generates sunlight by receiving sunlight that has passed through the window 23 on the upper surface thereof and entered the case 20.

  The solar cell 15 is electrically connected to the motor 4 b of the blower 4. Therefore, when electric power is generated by the solar cell 15, the motor 4b is driven by the electric power and the fan 4a rotates. Then, by rotating the fan 4a in this way, gas flows into the insertion cylinder part 19 from the lower end opening of the insertion cylinder part 19, and the gas is exhausted from the upper end opening of the insertion cylinder part 19 via the flow path 22. It reaches the hole 21 and is discharged toward the outside of the case 20.

  The forced deaeration device 1 is configured such that after the waterproof base 5, the ventilation layer 6, the waterproof layer 2, and the decylinder 3 described above are applied, an arbitrary decylinder 3 protruding on the waterproof layer 2 is removed by the exhaust pipe 14. It is installed on the waterproof layer 2 so as to surround it.

  Thereby, when sunlight is incident on the solar cell 15 of the installed forced deaerator 1 and electric power is generated, the blower 4 is driven by the electric power, and the ventilation layer between the waterproof base 5 and the waterproof layer 2 is generated. 6 is sucked into the exhaust cylinder 14 via the de-cylinder 3, and the air in the exhaust cylinder 14 is discharged to the outside of the forced deaerator 1 through the insertion cylinder portion 19 and the flow path 22. Is done.

  The forced deaeration device 1 described above is installed on the waterproof layer 2 so as to cover the decylinder 3 and uses a decylinder 3 that is not equipped with a blower that degass using natural convection. The gas between 5 and the waterproof layer 2 can be forcibly discharged, and blistering of the waterproof layer 2 can be reliably prevented. Further, by using the solar battery 15 as a power source for the blower 4, it is possible to save the trouble of wiring work or the like during battery replacement or installation.

  Furthermore, the forced deaeration device 1 of this example can make the forced deaeration device 1 compact by providing the solar cell 15 and the blower 4 at the upper end of the vertical cylindrical exhaust tube 14 that opens downward. In addition, the forced deaeration device 1 in the installed state can be made unobtrusive to the person using the rooftop or the veranda.

  Note that the forced deaeration device 1 may be used in a waterproof structure of a close construction method in which the waterproof layer 2 is directly formed on the waterproof base 5.

It is explanatory drawing which shows the waterproof structure which installed the forced deaeration apparatus of an example of embodiment of this invention. It is explanatory drawing of a forced deaeration apparatus same as the above. It is explanatory drawing which shows the waterproof structure before installing a forced deaeration apparatus same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Forced deaeration device 2 Waterproof layer 3 Decylinder 4 Blower 14 Exhaust tube 15 Solar cell

Claims (2)

  A forced deaeration device that exhausts gas between a waterproof base and a waterproof layer through a decylinder projecting upward from the waterproof layer, and is installed on the waterproof layer so as to surround the entire decylinder. A cylinder, a blower that sucks the gas between the waterproof base and the waterproof layer through the decylinder in the exhaust pipe into the exhaust pipe and discharges the gas to the outside, and a sun provided in the exhaust pipe serving as a power source for driving the blower A forced deaeration device comprising a battery.   2. The forced deaeration device according to claim 1, wherein the exhaust pipe is formed in a vertical cylinder shape that opens downward, and the solar cell and the blower are provided at an upper end portion of the exhaust pipe.

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