JPS5929884A - Gas feeder - Google Patents

Abstract

PURPOSE:To promptly perform a process of gas supply in manufacture of a double-layer transparent plate, by simultaneously supplying gas to each space with different volume. CONSTITUTION:Pipes 6B, 6D, 6F, 6H, 6J out of the feed pipe group 6A-6J are inserted into each space 18 of double-layer transparent plates 15A-15E, while valves 5B, 5D, 5F, 5H, 5J out of the flow regulating valve group of 5A-5J are opened, and the rest of the valves are left as closed. Next, under a condition in which select switch group of 10A-10J are placed in a bottom position, the first operation switch 8A is pressed to drive the first time limit device 8, and solenoid valves 7B, 7D, 7F, 7H, 7J are opened to simultaneously feed heat insulating gas to each space 18 for five minutes.

Description

Detailed Description of the Invention (A) Field of the Invention The present invention supplies a heat insulating gas, such as A, r, or SF gas having a higher specific gravity than air, to one or more layers formed in a multilayer transparent plate. The present invention relates to gas supply devices, and relates to gas supply devices for manufacturing multilayer transparent plates that are applied to doors and windows of houses, warehouses, and refrigerators.

(B) Background art and its problems A multilayer transparent plate is constructed by airtightly joining at least two transparent plates with a predetermined distance and a frame member interposed between the peripheral edges of the transparent plates. Its use is rapidly expanding as it has good insulation properties and is resistant to condensation.

In addition, for the purpose of increasing the heat insulation properties of the multilayer transparent plate or increasing the sound insulation properties, a gas having a lower thermal conductivity than air or a gas having a higher specific gravity than air, such as Ar or SF, may be used as the gas sealed in the internal space. Multilayer transparent plates using insulating gas are now on sale.

However, the gas supply device that supplies insulating gas to these multilayer transparent plates has a simple configuration in which a flow rate control valve is installed in the middle of a supply pipe that extends directly from the cylinder, and multiple multilayer transparent plates are installed in parallel. When supplying gas to each space at the same time,
This method requires a plurality of devices with the same configuration, which has the drawback of requiring time and effort to operate. In addition, two types of multilayer transparent plates with different spatial volumes or two layers of spaces with different spatial volumes can be formed.
When a plurality of multilayer transparent plates are arranged in parallel, it is difficult to supply gas to each of the spaces at the same time, and furthermore, the flow rate of the gas cannot be properly controlled.

(c) An object of the present invention is to simultaneously supply gas to spaces of different volumes with a simple operation, thereby speeding up the gas supply process in the production of a multilayer transparent plate.

(d) Outline of the present invention A group of supply pipes that supply gas to each space of a plurality of multilayer transparent plates arranged in parallel, a group of solenoid valves provided in the middle of each of the group of supply pipes, A flow control valve group that connects corresponding bases of the supply pipe group, a header that diverts gas from the cylinder to the flow control valve group, and a time limit for opening the solenoid valve group when driven. and a selection switch group that makes the "opening" time of any one of the solenoid valves different from the "opening time" of other solenoid valves, and , a gas supply device that simultaneously supplies insulating gas commensurate with the space volume.

(E) Embodiment of the present invention FIG. 1 shows an embodiment of the present invention, in which (1) is a gas supply device, which includes a substrate (2) and a control box (3) provided on this substrate.
), a header (4) provided on the substrate, a group of flow control valves (5A) to (5J) provided linearly at intervals on the header, and a group of flow rate control valves. A group of supply pipes (6A) whose bases are connected to opposing flow rate control valves
~ (6J), and a solenoid valve group (7A) provided in the middle of opposing supply pipes of this supply pipe group and fixed to the board.
It is composed of ~(7J). The control box includes a first timer (8) consisting of a cycle timer that is driven for, for example, 5 minutes and sets the first gas supply time, a first operation switch (8A) that drives this timer, and the A second timer (8B) consisting of a first glue set switch (8B) that resets the first timer, and a cycle timer that operates for, for example, 10 minutes and sets the second gas supply time.
9), a second operation switch (9A) that drives the timer, and a second operation switch (9A) that resets the second timer.
Glue set switch (9B) and select switch group (IOA) to (IOJ) that can be switched in two steps in the vertical direction and set the 6" opening time of the opposing solenoid valve groups (7A) to (7J).
) and a pressure gauge 00 that displays the pressure of a regulator that finely adjusts the pressure of the insulating gas sent to the header (4). When the select switch group is switched to one side, when the first timer (8) is activated, the solenoid valves (7A) to (7J) are opened for, for example, 3 minutes, and the second
When the timer R (9) is activated, the solenoid valve group, for example 7
When the first timer (8) is activated, the solenoid valve group (7A)
- (7J) are opened for, for example, 5 minutes, and when the second timer (9) is driven, the solenoid valve group is opened for, for example, 10 minutes.

α bottle is a cylinder filled with insulating gas such as Ar or SF6, and the internal pressure and discharge pressure are displayed at the outlet of the cylinder.
A regulator (13A) and (13B) equipped with pressure gauges (13A) and (13B) is provided, and a hose (04) extending to the header (4) is connected thereto.

(15A) to (1,5E) are a plurality of multilayer transparent plates erected on a mount, and these transparent plates are composed of two transparent plates (16A) (16B) as shown in Figures 2 and 3. , a frame member a, and a space Q frame defined by both transparent plates and the frame member, and the frame member has a supply pipe group (
A passageway (a) for guiding air from space 0 to the outside is formed.

Next, the supply of insulating gas to each space o barrel of the multilayer transparent plates (15A) to (15E) will be explained with reference to FIGS. 1 and 2.

First, (6)3) of the supply pipe group (6A) to (6J)
(6D) (6F) (6)? ) (6J) into each space θ of the multilayer transparent plates (15A) to (15B), and (5B) (5
D) Open (5F) (5H) (5J) and leave the rest closed as N. Next, select switch group (IOA) ~ (I
With the OJ) in the lower position, press the first operation switch (
8A) to drive the first timer (8) and open the solenoid valves (7B) (7D) (7F) (7HX7J).
Then, as shown by arrow G in FIG. 2, adiabatic gas is simultaneously supplied to each space Q~ for 5 minutes. Each space (to) associated with this supply
The air inside should be gradually pushed out to the outside as shown by arrow A.

When SF and gas are supplied to the space 08) having a volume of 26 by such gas supply, the characteristics shown in FIG. 6 are obtained. According to FIG. 6, SFe gas was supplied to the space 0 frame for 5 minutes at a rate of 1.5 l, 1.75 e, 2.
90% or more h in any supply amount of O4, 2, 41
I was able to get a good conversion rate.

Figures 1 and 5 show three transparent plates (16A, ) (1
, 6B) (16c) and two frame parts (17A,) (
1, 7B) and two-layer spaces (], 8A) (18B) defined by the transparent plate and the frame H and having different volumes (15A') to (15E'). ), and in the case of gas supply, the supply pipes (6A) (6C) (6B) (6G) (6I
) in each small volume space (18A, ), (6B) (6
D) (6F) (6H) ((5J) are inserted into each large volume space (18B), and the flow control valve group (5A) to (5J)
Open the select switch (IOA) (IOC) (
I 0E) (IOG) (IOI) upwards, (IOB
) (1,01)) (], 0F) (101-I) (I
After positioning the OJ) downward, press the second operation switch (9
Press A) to activate the second timer (9) and open the solenoid valves (7A, ) (7C) (7E) (7G) (7I) for 7 minutes, (7J3) (7D) (7F). (7H) (7J)
are opened for 10 minutes, and insulating gas is simultaneously supplied to spaces (18A,) (18B) with different volumes.The flow rate control valve group (18A,) (18B) is By adjusting 5A) to 5J and changing their diameters, it is possible to supply gas appropriately.

Therefore, according to the gas supply device (1), a plurality of multilayer transparent plates (15A) to (
15E) can simultaneously supply an appropriate amount of insulating gas to the select switch group (IOA) to (1, O, T
) by appropriately selecting solenoid valve groups (7A) to (7
, J), a plurality of multilayer transparent plates forming two-layer spaces (18A818B) with different volumes in order to be able to change the "opening" time of the solenoid valve facing the selected select switch. An appropriate amount of insulating gas can be simultaneously supplied to (15A') to (15E'). Note that gas can be supplied in the same manner to a plurality of multilayer transparent plates of two or more types in which single-layer spaces with different volumes are formed.

(f) Effect of the present invention: Insulating gas can be simultaneously supplied in an appropriate amount to a plurality of multilayer transparent plates having the same or different spatial volumes, and the gas supply process for multilayer transparent plates can be accelerated.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention, and FIG. 1 is a perspective view of a gas supply device, FIG. 2 is a perspective view of a multilayer transparent plate that receives gas supply and is heated to °C, and FIG. 3 is a perspective view of a gas supply device. I' sectional view, FIG. 4 is a perspective view of essential parts showing another embodiment of the present invention, and FIG. 5 is FIG.
-1 sectional view and FIG. 6 are characteristic diagrams accompanying gas supply. (4) Header, (5A) to (5J) Flow control valve group, (6A) to (6J) Supply pipe group, (7A) to
(7J)...Solenoid valve group, (8) (9)...Timer, (], IOA~(IOJ)...Select switch group, (15A)~(15E) and (158') ~(15B
')...multilayer transparent plate, (18) (1,8A) (1
8B)...Space. Figure 2 Figure 3 Procedures Amendment (Method) December 13, 1980 Dear Commissioner of the Japan Patent Office 2 Name of the invention Gas supply device Person making the amendment Patent applicant Address 2-chome, Keihan Hondori, Moriguchi City 18 Name (188) Sanyo Electric Co., Ltd. Representative Kungai Iue 1 person 4, Agent address 2-18-6, Keihan Hondori, Moriguchi City, Subject of amendment Attached drawing 7, contents of amendment Fig. 6 attached. Correct accordingly.

Claims (1)

[Claims] 1. A device for simultaneously supplying insulating gas to each space of a plurality of multilayer transparent plates arranged in parallel, including a group of supply pipes for supplying gas to each of the spaces, and a group of supply pipes in the middle of each of the group of supply pipes. a group of solenoid valves provided, a group of flow control valves that connect corresponding bases of the group of supply pipes, a header that divides gas from a cylinder to the group of flow control valves, and a group of solenoid valves that are activated when driven. A gas supply device comprising a timer for setting the solenoid valve to "open", and a select switch group for making the "open" time of any one of the solenoid valves different from the "open" time of other solenoid valves.