JP2012184131A - Double glazing structure, door for cold insulation showcase, and method for measuring inert gas concentration of the double glazing structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a double glazing structure, capable of measuring the concentration of inert gas filled in the double glazing structure without decomposing the double glazing structure, a cold insulation showcase door, and a method for measuring an inert gas concentration of the double glazing structure.SOLUTION: In this double glazing structure 10, a film 24 is not included on the whole surface of a first glass plate 14 but a first transmission part 26 having no film 24 on a part thereof is included on the first glass plate 14. Similarly, concerning the surface of a third glass plate 18, the film 24 is not included on the whole surface of the third glass plate 18 but a second transmission part 28 having no film 24 on a part thereof is included on the third glass plate 18. When measuring the concentration of inert gas in a first hollow layer 15 and in a second hollow layer 17, an inert gas concentration measuring device 30 shown in Fig.4 is used. Hereby, each concentration of inert gas in the first hollow layer 15 and in the second hollow layer 17 can be measured individually without decomposing the double glazing structure 10.

Description

  The present invention relates to a multilayer glass structure, a door for a cold showcase, and a method for measuring an inert gas concentration of the multilayer glass structure.

  Patent Document 1 discloses that a double-glazed glass structure is used for a door of a cold storage showcase installed in a convenience store or the like. The door is composed of the multilayer glass structure and a sash attached to the peripheral edge of the multilayer glass structure, and a handle is attached to the front surface of the sash. When the customer opens and closes the handle, the door is opened and closed back and forth. In Patent Document 1, a transparent conductive film such as fluorine-doped tin oxide or ITO (tin-doped indium oxide) is provided on the entire glass surface of the multilayer glass structure, and the glass surface is heated by energizing this. Thus, fogging on the glass surface is prevented.

  On the other hand, Patent Document 2 discloses forming Low-E (low emission film) for improving heat insulation performance on the entire surface of the glass plate constituting the multilayer glass structure on the hollow layer side. Patent Document 2 also discloses that the hollow layer is filled with gas in consideration of heat insulation performance, and an inert gas such as sulfur hexafluoride gas, argon gas, or krypton gas is used as the gas. This is disclosed in Patent Document 3.

  As described above, in the conventional multilayer glass structure, a film is formed on the glass surface of the glass plate constituting the multilayer glass structure, and the hollow layer between the glass plates is filled with an inert gas. . This inert gas leaks little by little when, for example, the handling is bad, and this affects the performance of the multilayer glass structure, so it is required to measure the concentration of the inert gas at a predetermined time. There is a case.

  As a gas concentration measuring device for doors, there is a commercially available product (manufactured by Gasglass: a handheld device) that measures the inert gas concentration in the hollow layer from the outside of the multilayer glass structure. The concentration of inert gas cannot be measured due to obstruction. For this reason, the method for measuring the inert gas concentration of a multilayer glass structure having the above-mentioned film is to make a hole in a part of the multilayer glass structure, take out the gas in the hollow layer from this hole, It was possible to measure with a gas concentration measuring device.

JP 2006-336884 A JP 2005-61075 A JP 2008-24546 A

  However, opening a hole in a part of the multilayer glass structure when measuring the concentration of the inert gas means decomposing the multilayer glass structure. Therefore, it was difficult to reuse the multilayer glass structure in which the inert gas concentration was measured.

  This invention is made | formed in view of such a situation, and can measure the density | concentration of the inert gas with which the multilayer glass structure was filled, without decomposing | disassembling the multilayer glass structure which has a film | membrane. An object of the present invention is to provide a method for measuring an inert gas concentration of a multilayer glass structure, a door for a cold showcase, and a multilayer glass structure.

  In order to achieve the above object, the present invention provides a first glass plate, a second glass plate opposed to the first glass plate via a first hollow layer, and the second glass. A third glass plate disposed opposite to the plate via the second hollow layer, and a spacer for holding a peripheral edge of each of the first to third glass plates, the first to third With respect to the glass plate, a film is provided on at least one surface of each glass plate on the hollow layer side, and an inert gas is provided in each of the first hollow layer and the second hollow layer. In the filled multi-layer glass structure, a part of the surface of the first glass plate is provided with a first transmission part without the film, and a part of the surface of the third glass plate is Provided is a multilayer glass structure characterized in that a second transmission part without a film is provided.

  In order to achieve the above object, the present invention provides a door for a cold showcase, wherein a sash is attached to the peripheral edge of the multilayer glass structure of the present invention.

  In the door for a cold-insulated showcase of the present invention, the first transmissive part and the second transmissive part of the multilayer glass structure are provided at positions that do not overlap in a plan view of the multilayer glass structure. It is preferable that

  Furthermore, in the door for a cold storage showcase of the present invention, a hinge member is attached to one end side of the sash, a handle is attached to the other end side of the sash, and the first glass of the multilayer glass structure The plate is disposed inside the cold storage showcase, the third glass plate of the multilayer glass structure is disposed outside the cold storage case, and the first transmission portion is provided near the handle, The second transmission part is preferably provided in the vicinity of the hinge member.

  In order to achieve the above-mentioned object, the present invention brings the measurement end of the inert gas concentration measuring device into contact with the first transmission part of the multilayer glass structure of the present invention from the outside of the multilayer glass structure. And measuring the inert gas concentration of the first hollow layer, and connecting the measurement end of the inert gas concentration measuring device to the second transmission part of the multilayer glass structure outside the multilayer glass structure. The method for measuring the inert gas concentration of a double-layer glass structure is characterized in that the inert gas concentration of the second hollow layer is measured by contact with the second glass layer.

  The multi-layer glass structure of the present invention and the multi-layer glass structure for a cold insulation showcase are not provided with a film over the entire surface of the first glass plate, and the first without the film in a part thereof. The transmission part is provided. Similarly, the surface of the third glass plate is also provided with a second transmission part without the film on a part thereof. Here, the state in which the film is provided on the entire surface means that the function of the film should not be affected even if there is a slight portion where there is no film at the spacer installation position described later.

  In the present invention, the inert gas concentration of the first hollow layer is measured by the inert gas concentration measuring device using the first transmission part, and the second hollow layer is used by using the second transmission part. The inert gas concentration is measured by an inert gas concentration measuring device.

  Thereby, according to this invention, the density | concentration of the inert gas with which the multilayer glass structure was filled can be measured, without decomposing | disassembling the multilayer glass structure which has a film | membrane. In addition, according to the present invention, the inert gas concentration of a new multilayer glass structure can be reduced by adding an inert gas concentration measurement step to the inspection process at the time of shipment of the multilayer glass structure. Measurement can be easily performed without disassembling the structure.

  Further, when the first transmission part and the second transmission part are provided at a position where they overlap each other in a plan view of the multilayer glass structure, the overlapping surface of the first transmission part and the second transmission part is Compared with other surfaces provided with a film, the transparency becomes larger, which gives an uncomfortable feeling. For this reason, it is preferable that the 1st permeation | transmission part and the 2nd permeation | transmission part are provided in the position which does not overlap in planar view of a multilayer glass structure. Thereby, since the said transparency is reduced, the said discomfort is reduced.

  On the other hand, the door for a cold showcase has a hinge member attached to one end side of the sash and a handle attached to the other end side of the sash. That is, by holding the handle and moving the cold insulation showcase door back and forth, the cold insulation showcase door opens and closes around the hinge member.

  When measuring the inert gas concentration of a multi-layer glass structure with the cold insulation showcase door attached to the cold insulation showcase, the cold air inside the cold insulation showcase can be measured without leaking as much as possible. Required.

  Therefore, the first glass plate of the multilayer glass structure is arranged inside the cold storage showcase, and the third glass plate of the multilayer glass structure is arranged outside the cold storage case. In the case of the case door, it is preferable that the first transmission part is provided in the vicinity of the handle and the second transmission part is provided in the vicinity of the hinge member.

  In other words, if the first transmission part is disposed in the vicinity of the hinge, the inert gas concentration measuring device cannot be disposed at the measurement position unless the opening angle of the cold showcase door is increased. For this reason, the amount of cold air leaked in the cold storage showcase increases. In this invention, since the 1st permeation | transmission part is provided in the vicinity of a handle, even if it makes the opening angle of the door for cold storage showcase small, an inert gas concentration measuring apparatus can be arrange | positioned in a measurement position. Thereby, the amount of cold air leaked out in the cold insulation showcase can be suppressed. Further, in the present invention, since the second transmission part is provided in the vicinity of the hinge part, the inert gas concentration measuring device can be arranged at the measurement position without opening the cold insulation showcase door.

  According to the multilayer glass structure of the present invention, the door for a cold insulation showcase, and the inert gas concentration measuring method of the multilayer glass structure, the multilayer glass structure without decomposing the multilayer glass structure having a film. The concentration of the inert gas filled in the can be measured.

Front perspective view of a door for a cold insulation showcase provided with a multilayer glass structure according to an embodiment Sectional drawing which follows the AA line of the multilayer glass structure shown in FIG. Sectional drawing which follows the BB line of the multilayer glass structure shown in FIG. Perspective view of essential part showing concentration measurement by inert gas concentration measurement Top view showing the concentration measurement state when the first transmission part is in the vicinity of the hinge axis Top view showing the concentration measurement state when the first transmission part is in the vicinity of the handle Top view showing the concentration measurement state when the second transmission part is in the vicinity of the hinge axis

  Hereinafter, preferred embodiments of a multilayer glass structure, a cold insulation showcase door, and a method for measuring an inert gas concentration of a multilayer glass structure according to the present invention will be described in detail according to the accompanying drawings.

  FIG. 1 is a front view of a cold insulation showcase door 12 provided with a multilayer glass structure 10 according to an embodiment of the present invention. 2 is a longitudinal sectional view of the cold insulation showcase door 12 taken along the line AA in FIG. 1, and FIG. 3 is a longitudinal sectional view of the cold insulation showcase door 12 taken along the line BB in FIG.

  In the embodiment described below, an example in which the multilayer glass structure 10 is applied to a cold insulation showcase door 12 is illustrated. This multilayer glass structure 10 is a multilayer glass structure that constitutes a window of a building. It can also be applied to.

  The multilayer glass structure 10 is opposed to the first glass plate 14 located on the inside (IN) side of the cold storage showcase, the first glass plate 14 and the first hollow layer 15, and A second glass plate 16 located on the outer (OUT) side, a third glass plate 18 opposed to the second glass plate 16 via the second hollow layer 17 and located further outside I have. And this multilayer glass structure 10 is comprised by the peripheral part of the 1st, 2nd and 3rd glass plates 14, 16, and 18 being hold | maintained via the spacers 20 and 22. As shown in FIG.

  In addition, the multilayer glass structure 10 includes membranes 24 on the surfaces of the hollow layers 15 and 17 sandwiched between the first glass plate 14, the second glass plate 16, and the third glass plate 18. ing. In addition, regarding the 2nd glass plate 16, it is preferable that the film | membrane of at least 1 layer is installed. Examples of the film 24 include a low radiation film, a conductive film, and an anti-icing film.

  The low-emission film is preferably a thin film, and is a film (zinc oxide / silver / zinc oxide) in which a film mainly composed of silver is sandwiched between oxide thin films mainly composed of zinc. ) Is preferred. In order to lower the low emissivity, a laminate film (zinc oxide / silver / zinc oxide / silver / zinc oxide) in which the laminate is doubled is more preferable. Since this laminated film has high transmittance and low radiation, the inside of the show window can be easily seen, and the heat insulation performance is also suitably maintained.

Further, the conductive film only needs to have a function of energizing and heating the glass plate, and may be a conductive thin film, a glass plate with a heating wire installed thereon, and a silver print for heating. It may be installed. Among these, those using a conductive thin film that allows the inside of the show window to be easily observed are preferable, and materials for the conductive thin film are antimony-doped tin oxide (Sb dopep SnO ₂ ), bismuth-doped tin oxide (Bi). Dopep SnO ₂ ) or fluorine doped tin oxide (F dopep SnO ₂ ) is preferred. Fluorine-doped tin oxide is preferable because of its low cost.

Furthermore, examples of the anti-icing film include a hydrophilic film having a TiO ₂ film and an SiO ₂ film in this order.

  On the other hand, the first hollow layer 15 and the second hollow layer 17 are filled with an inert gas G. Examples of the inert gas G include krypton (Kr) gas and argon (Ar) gas, which are heat insulating gases having a thermal conductivity smaller than that of air.

  The thickness of the first, second, and third glass plates 14, 16, and 18 is not particularly limited, but it is preferably 2.5 to 5 mm, which has been used as a window even for a single sheet. If necessary, tempered glass and laminated glass may be applied to one or all three sheets.

  The thicker the first hollow layer 15 and the second hollow layer 17, the better the heat insulation effect, but the thicker the fit as a door, the thicker the first hollow layer 15 and the second hollow layer 17. The thickness is preferably 2 to 12 mm. The spacers 22 and 22 are made of resin.

  In addition, the glass as used in this invention shall include both inorganic glass and organic glass. Organic glass refers to a transparent resin such as acrylic.

  The cold insulation showcase door 12 is generally called a walk-in door, and a small one is a reach-in door, depending on the size of the showcase body. This embodiment is also included. Further, the number of doors used is not limited to one and may be two or more.

  By the way, in the multilayer glass structure 10 according to the embodiment, the film 24 is not provided on the entire surface of the first glass plate 14, and the first transmission part 26 without the film 24 is partly provided on the first glass plate 14. 1 glass plate 14 is provided. Similarly, the surface of the third glass plate 18 is not provided with the film 24 on the entire surface of the third glass plate 18, and the second transmission part 28 without the film 24 is formed in part of the second transmission part 28. 3 glass plates 18 are provided.

  The first transmission part 26 has a predetermined width, and is provided at an inclination in the lower right corner of the first glass plate 14 in FIG. The upper end of the first transmission part 26 reaches the right side of the first glass plate 14, and the lower end of the first transmission part 26 reaches the lower side of the first glass plate 14. Yes.

  Similarly, the second transmission portion 28 has a predetermined width, and is provided at the lower left corner of the third glass plate 18 in FIG. 1, and its upper end is the left side portion of the third glass plate 18. And the lower end thereof reaches the lower side of the third glass plate 18.

  The arrangement positions of the first transmission part 26 and the second transmission part 28 are not limited to the above positions, and the inert gas of the first hollow layer 15 is measured by an inert gas concentration measuring device described later. Any position may be used as long as the concentration of the inert gas in the second hollow layer 17 can be measured. Further, the first transmission part 26 and the second transmission part 28 are formed when the film 24 is formed on the first glass plate 14 and the third glass plate 18. The portion corresponding to the two transmitting portions 28 can be provided by masking with a masking member.

  When measuring the concentration of the inert gas in the first hollow layer 15 and the second hollow layer 17, an inert gas concentration measuring device (manufactured by Gasglass: handheld device) 30 shown in FIG. 4 is used. The inert gas concentration measuring device 30 can measure the concentration of the inert gas in the first hollow layer 15 or the second hollow layer 17 from the outside of the multilayer glass structure 10. That is, from the outside of the multilayer glass structure 10, the measurement end 32 of the inert gas concentration measurement device 30 is brought into contact with the first transmission unit 26 or the second transmission unit 28, and the first hollow layer 15. Alternatively, a high voltage is applied to the second hollow layer 17. At that time, gas molecules existing in the first hollow layer 15 or the second hollow layer 17 emit light, and the inert gas concentration measuring device 30 measures the intensity of the light emission. The wavelength of light emitted varies depending on the type of gas, and the emission intensity varies depending on the gas concentration (number of molecules). By measuring the emission intensity with the inert gas concentration measuring device 30, the concentration of the inert gas in the first hollow layer 15 and the second hollow layer 17 can be measured individually.

  Therefore, according to the inert gas concentration measurement method of the embodiment, the concentration of the inert gas filled in the multilayer glass structure 10 is measured without decomposing the multilayer glass structure 10 having the film 24. be able to. Further, if this method is used, the inert gas concentration of the new multilayer glass structure 10 is increased by adding an inert gas concentration measurement process to the inspection process at the time of shipment of the multilayer glass structure 10. Measurement can be easily performed without decomposing the multilayer glass structure 10.

  Electrons are discharged from the measuring end 32 of the inert gas concentration measuring device 30. For this reason, the measurement position by the measurement end 32 is set to a position separated from the metal sash 34 constituting the cold insulation showcase door 12 by a predetermined amount.

  On the other hand, when the first transmission part 26 and the second transmission part 28 are provided at a position where they overlap each other in the plan view of the multilayer glass structure 10, the first transmission part 26 and the second transmission part 28 Since the transparent surface is more transparent than the other surface on which the film 24 is provided, it gives an uncomfortable feeling. For this reason, the first transmission part 26 and the second transmission part 28 are provided at positions that do not overlap as shown in FIG. 1 in the plan view of the multilayer glass structure 10. Thereby, since the said transparency is reduced, the said discomfort is reduced. Moreover, the position which does not overlap also from the point of heat insulation performance is preferable.

  The cold insulation showcase door 12 is configured by attaching a sash 34 made of metal (for example, aluminum) to the edge of the multilayer glass structure 10.

  The cold insulation showcase door 12 is attached to the cold insulation showcase door frame 40 (see FIGS. 5 to 7) via hinge shafts 36, 36 and holds the handle 38 to move the cold insulation showcase door 12 forward and backward. As a result, the door 12 for the cold insulation showcase is opened and closed around the hinge shafts 36 and 36.

  The hinge shafts 36 and 36 are attached to the upper and lower ends of a sash 34A disposed along the left side portion of the multilayer glass structure 10 in FIG. 1, and the handle 38 is a right side portion of the multilayer glass structure 10. Is attached to the approximate center of the sash 34B disposed along the sash 34B.

  When measuring the inert gas concentration of the multi-layer glass structure 10 with the cold insulation showcase door 12 attached to the door frame 40, measure the cold air in the cold insulation showcase without leaking to the outside as much as possible. Is required.

  Therefore, the first glass plate 14 of the multilayer glass structure 10 is disposed inside the cold storage showcase, and the third glass plate 18 of the multilayer glass structure 10 is disposed outside the cold storage case. In the case of the cold insulation showcase door 12, it is preferable that the first transmission portion 26 is provided in the vicinity of the handle 38 and the second transmission portion 28 is provided in the vicinity of the hinge shaft 36.

That is, when the first transmitting portion 26 is arranged in the vicinity of the hinge shaft 36, as shown in the top view shown in FIG. 5, to be increased opening angle theta ₁ of cold showcase door 12, inert The gas concentration measuring device 30 cannot be disposed at the measurement position (first transmission part 26). For this reason, the amount of cold air leaked in the cold storage showcase increases.

On the other hand, in the cold insulation showcase door 12 of the embodiment, the first transmission part 26 is provided in the vicinity of the handle 38, so the cold insulation showcase door 12 is as shown in the top view of FIG. even by reducing the angle of opening theta _2, it can be arranged with an inert gas concentration measuring device 30 to measure the position (first transmitting portion 26). Thereby, the amount of cold air leaked out in the cold insulation showcase can be suppressed.

  Further, in this cold insulation showcase door 12, since the second transmitting portion 28 is provided in the vicinity of the hinge shaft 36, the cold insulation showcase door 12 is not opened as shown in the top view of FIG. The inert gas concentration measuring device 30 can be disposed at the measurement position (second transmission part 28).

  DESCRIPTION OF SYMBOLS 10 ... Multi-layer glass structure, 12 ... Door for cold storage showcases, 14 ... 1st glass plate, 15 ... 1st hollow layer, 16 ... 2nd glass plate, 17 ... 2nd hollow layer, 18 ... 3rd glass plate, 20 ... spacer, 22 ... spacer, 24 ... membrane, 26 ... first transmission part, 28 ... second transmission part, 30 ... inert gas concentration measuring device, 32 ... measurement end, 34 ... Sash 36 ... Hinge shaft 38 ... Handle 40 ... Door frame

Claims (5)

A first glass plate, a second glass plate arranged opposite to the first glass plate via a first hollow layer, and an opposite arrangement arranged via the second glass plate and the second hollow layer The third glass plate and a spacer for holding the peripheral edge of each of the first to third glass plates, and the hollow of each glass plate with respect to the first to third glass plates In the multilayer glass structure in which a film is provided on at least one of the layer-side surfaces, and the first hollow layer and the second hollow layer are filled with an inert gas,
Part of the surface of the first glass plate is provided with a first transmission part without the film, and part of the surface of the third glass plate is provided with a second transmission part without the film. A multilayer glass structure characterized by being made.   A sash is attached to the peripheral edge of the multi-layer glass structure according to claim 1.   3. The cold insulation showcase according to claim 2, wherein the first transmission part and the second transmission part of the multilayer glass structure are provided at positions that do not overlap in a plan view of the multilayer glass structure. door. A hinge member is attached to one end of the sash, and a handle is attached to the other end of the sash,
The first glass plate of the multilayer glass structure is disposed inside the cold storage showcase, the third glass plate of the multilayer glass structure is disposed outside the cold storage case,
4. The cold insulation showcase door according to claim 3, wherein the first transmission part is provided in the vicinity of the handle, and the second transmission part is provided in the vicinity of the hinge member.   A measurement end of an inert gas concentration measuring device is brought into contact with the first transmission part of the multilayer glass structure according to any one of claims 1 to 4 from the outside of the multilayer glass structure, While measuring the inert gas concentration of the hollow layer, the measurement end of the inert gas concentration measuring device is brought into contact with the second transmission part of the multilayer glass structure from the outside of the multilayer glass structure. A method for measuring an inert gas concentration of a multilayer glass structure, wherein the inert gas concentration of the second hollow layer is measured.

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