JP2009226564A - Glazing channel cutting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a glazing channel cutting device capable of accurately and easily cutting a glazing channel and advantageous for increasing productivity. <P>SOLUTION: This glazing channel cutting device 10 comprises a moving mechanism 19, first and second support members 16, 18, first to fourth cutters 20, 22, 24, 26, four heaters 28, first and second retaining members 30, 32, a positioning member 34, and a guide mechanism 40. When first and second arms 12, 14 are moved in the closing directions, first to fourth cutters 20, 22, 24, 26 are brought into contact with the glazing channel 4 with a double-glazing panel 2 held by the retaining surfaces 3010, 3210 of the first and second retaining members 30, 32. When the first and second arms 12, 14 are further moved, the edges of the first to fourth cutters 20, 22, 24, 26 are brought into contact with the front and rear surfaces of the double-glazing panel 2, and the glazing channel 4 is cut off. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a glazing channel cutting device for cutting a glazing channel applied to a peripheral portion of a multilayer glass panel.

A multi-layer glass panel is generally constituted by forming an air layer between two glass plates and a spacer between these two glass plates.
Since the double-glazed glass panel having such a structure has excellent heat insulation properties, it contributes to energy saving by being mounted on a sash of a house or a building.

As a method of mounting such a multi-layer glass panel on a sash, a pre-formed glazing channel is manually fitted to the peripheral portion of the multi-layer glass panel, and the peripheral portion of the multi-layer glass panel is sashed through the glazing channel. A method of mounting is known.
This method is disadvantageous in improving productivity because the glazing channel is manually attached to the peripheral edge of the multi-layer glass panel.
Therefore, in order to improve productivity, a method has been proposed in which a glazing channel is formed on the peripheral portion of the multilayer glass panel by applying the resin material to the peripheral portion of the multilayer glass panel while extruding it using an extruder. (See Patent Document 1).
According to the above method, the glazing channel 4 is formed by applying the resin material to the peripheral edge portion of the multilayer glass panel 2, and in this case, application of the resin material is started as shown in FIG. At the start point 4A and the end point 4B after the application, the amount of the resin material extruded from the extruder becomes unstable, so that the shape of the start point 4A and the end point 4B becomes thinner than the other parts. It is difficult to obtain a glazing channel 4 having a desired shape.
Therefore, as shown in FIG. 6B, the portion of the glazing channel 4 including the start point portion 4A and the end point 4B of the glazing channel 4 is cut, and as shown in FIG. 6C, it corresponds to the cut portion. The glazing channel 4 is formed into a desired shape by fitting a molded part 6 of a glazing channel having dimensions into the cut portion.
JP-A-11-210335

However, since the glazing channel 4 has been cut manually, there is a disadvantage that the work is complicated and the size of the cut portion varies.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a glazing channel cutting device that can cut a glazing channel accurately and easily, and is advantageous in improving productivity. It is in.

  In order to achieve the above object, the present invention provides two locations in which the glazing channels applied to the peripheral portions of the front and back surfaces forming both surfaces in the thickness direction of the multilayer glass panel are spaced in the extending direction of the glazing channels. A glazing channel cutting device that cuts at a first support member disposed to face the front surface of the multilayer glass panel and a second support disposed to face the back surface of the multilayer glass panel. The member and the first support member are moved in a direction to be in contact with and away from the front surface, and the second support member is moved with respect to the back surface in conjunction with the contact and separation of the first support member to the front surface. A moving mechanism for moving in a contacting / separating direction and a first support member which is supported in parallel with a distance from each other, and abuts on the surface at right angles as the first support member approaches the surface. A thin plate-shaped first cutter and a second cutter, and a thin plate-shaped first cutter that is supported in parallel by the second support member at a distance from each other and abuts on the back surface at right angles as the second support member approaches the back surface. 3 cutters and 4th cutters, and a heater for heating the first to fourth cutters.

  According to the present invention, the glazing channel can be cut mechanically and automatically, and the glazing channel can be cut accurately and easily, which is advantageous in improving productivity.

Next, a glazing channel cutting apparatus according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a front view of a glazing channel cutting device 10 according to the present embodiment, FIG. 2 is a rear view of the glazing channel cutting device 10, and FIG. 3 is a side view of the glazing channel cutting device 10.
As shown in FIGS. 1 to 3, the glazing channel cutting device 10 includes a moving mechanism 19, first and second support members 16 and 18, first to fourth cutters 20, 22, 24, 26, and four heaters 28. The first and second pressing members 30, 32, the positioning member 34, the guide mechanism 40, and the like are configured.
The glazing channel cutting device 10 has two glazing channels 4 applied to the peripheral portions of the front surface and the back surface forming both surfaces in the thickness direction of the multilayer glass panel 2 at intervals in the extending direction of the glazing channel 4. It cuts with.

The first support member 16 is disposed so as to face the surface of the multilayer glass panel 2, and the second support member 18 is disposed so as to face the back surface of the multilayer glass panel 2, and the first and second support members 16, 18 is moved by a moving mechanism 19.
The moving mechanism 19 moves the first support member 16 in a direction in which the first support member 16 is brought into contact with or separated from the front surface, and the second support member 18 is brought into contact with the rear surface in conjunction with the contact with or separated from the front surface of the first support member 16. Move it away.
The moving mechanism 19 includes a first arm 12 and a second arm 14.
As shown in FIG. 3, the first arm 12 includes a base portion 1202 that extends linearly, an intermediate portion 1204 that is bent from the tip of the base portion 1202, and a direction parallel to the base portion 1202 from the tip of the intermediate portion 1204. The front part 1206 which exists is provided.
The second arm 14 includes a base portion 1402 extending linearly, an intermediate portion 1404 bent from the tip of the base portion 1402, and a tip portion 1406 extending from the tip of the intermediate portion 1404 in a direction parallel to the base portion 1402. I have.
The first and second arms 12, 14 are connected to the center of the intermediate portions 1204, 1404 so as to be swingable via the support shaft 15. When the two base portions 1202, 1402 are separated and approached, the two front portions Reference numerals 1206 and 1406 are also configured to be separated and approach each other.
In addition, a tension coil spring 36 is stretched between a location near the base 1202 of the intermediate portion 1204 of the first arm 12 and a location near the front portion 1406 of the intermediate portion 1402 of the second arm 14. A tension coil spring 36 is stretched between a location near the tip portion 1206 of the intermediate portion 1204 and a location near the base portion 1402 of the intermediate portion 1402 of the second arm 14.
By these tension coil springs 36, the first and second arms 12 and 14 are constantly urged in a direction in which the base portions 1202 and 1402 are separated from each other and the front portions 1206 and 1406 are separated from each other.
The swinging operation of the first and second arms 12 and 14, that is, the movement mechanism 19 may be driven manually by an operator, or automatically by a work robot or the like. Good.

As shown in FIGS. 1 and 3, the first support member 16 includes a main body 1602 and two connecting plate portions 1604.
The main body 1602 has an elongated shape, and the longitudinal direction thereof is parallel to the extending direction of the support shaft 15.
The two connecting plate portions 1604 connect the main body 1602 and the first arm 12.
The two connecting plate portions 1604 are provided on the upper surface of the main body 1602 so as to sandwich the tip portion of the tip portion 1206 of the first arm 12.
A long hole 1610 is formed in each connecting plate portion 1604, and two pins 1210 protruding from the front portion 1206 of the first arm 12 are inserted into the long holes 1610, respectively, so that the first arm 12 and the first support are supported. The member 16 is connected so as to be swingable.
Further, since the compression coil spring 38 is interposed between the main body 1602 and the tip portion 1206 of the first arm 12, the first support member 16 can be moved from the tip portion 1206 of the first arm 12 to the tip of the second arm 14. It is always urged in the direction approaching the portion 1406.
Due to the biasing force of the compression coil spring 38, the pin 1210 abuts on one edge of the elongated hole 1610 in the extending direction, whereby the maximum projecting position of the first support member 16 shown in FIG.

As shown in FIGS. 1 and 3, the second support member 18 includes a main body 1802 and two connecting plate portions 1804.
The main body 1802 has an elongated shape, and the longitudinal direction thereof is parallel to the extending direction of the support shaft 15.
The two connecting plate portions 1804 connect the main body 1802 and the second arm 14.
The two connecting plate portions 1804 are provided on the lower surface of the main body 1802 so as to sandwich the tip portion of the tip portion 1406 of the second arm 14.
A long hole 1810 is formed in each connecting plate portion 1804, and two pins 1410 protruding from the tip portion 1406 of the second arm 14 are inserted into the long holes 1810, respectively. The member 18 is connected so as to be swingable.
Further, since the compression coil spring 38 is interposed between the main body 1802 and the tip portion 1406 of the second arm 14, the second support member 18 can be moved from the tip portion 1406 of the second arm 14 to the tip of the first arm 12. It is always urged in the direction approaching the portion 1206.
By the urging of the compression coil spring 38, the pin 1410 abuts against one edge portion in the extending direction of the long hole 1810, whereby the maximum projecting position of the second support member 18 shown in FIG.

The first and second cutters 20, 22 have a rectangular plate shape with a uniform thickness, and the first support member 16 is supported on the lower surface of the main body 1602 facing the second support member 18.
The first and second cutters 20 and 22 are spaced in the longitudinal direction of the main body 1602 and are parallel to each other, and their surfaces are supported in a state of being orthogonal to the longitudinal direction of the main body 1602.
Edge portions located at the tips of the first and second cutters 20 and 22 are cutting edges, respectively, parallel to the lower surface of the main body 1602 and located at the same height.
The third and fourth cutters 24, 26 have a rectangular plate shape with a uniform thickness, and the second support member 18 is supported on the upper surface of the main body 1802 facing the first support member 16.
The third and fourth cutters 24 and 26 are spaced in parallel with each other in the longitudinal direction of the main body 1802 and are supported in a state where their surfaces are orthogonal to the longitudinal direction of the main body 1802.
Edge portions located at the tips of the third and fourth cutters 24 and 26 are cutting edges, and are parallel to the upper surface of the main body 1802 and at the same height.
When viewed from the thickness direction of the multilayer glass panel 2, the location of the first cutter 20 in contact with the front surface matches the location of the third cutter 24 in contact with the back surface, and on the surface The location of the second cutter 22 in contact with the location of the fourth cutter 26 in contact with the back surface is matched.
As shown in FIG. 1, the first to fourth cutters 20, 22, 24, and 26 are each heated by incorporating a heater 28, thereby softening and cutting the glazing channel 4. .

The first pressing member 30 is configured to be elastically contactable with a portion of the surface of the multilayer glass panel 2 provided on the first support member 16 and not coated with the glazing channel 4.
In the present embodiment, the first pressing member 30 includes an attachment piece 3002, a shaft portion 3004, a pressing portion 3006, and a compression coil spring 3008.
The attachment piece 3002 is provided so as to protrude from the center of the lower surface of the main body 1602 of the first support member 16.
The shaft portion 3004 is supported by a bearing portion provided on the attachment piece 3002 so as to be movable in the vertical direction and not to be removed.
The pressing portion 3006 has a pressing surface 3010 that is provided at the lower end of the shaft portion 3004 and can elastically contact the surface of the multilayer glass panel 2.
The compression coil spring 3008 is interposed between the attachment piece 3002 and the pressing portion 3006 and constantly urges the pressing portion 3006 in the protruding direction.
The maximum protrusion position of the pressing portion 3006 is determined by a stopper provided on the shaft portion 3004 coming into contact with the attachment piece 3002.
At this maximum protruding position, the pressing surface 3010 is positioned below the cutting edges of the first and second cutters 20 and 22, and before the cutting edges of the first and second cutters 20 and 22 come into contact with the glazing channel 4, The surface 3010 is configured to elastically contact the surface of the multilayer glass panel 2.

The 2nd pressing member 32 is comprised so that elastic contact is possible at the location of the back surface of the multilayer glass panel 2 in which the glazing channel 4 is not apply | coated.
In the present embodiment, the second pressing member 32 includes an attachment piece 3202, a shaft portion 3204, a pressing portion 3206, and a compression coil spring 3208.
The attachment piece 3202 is provided so as to protrude from the center of the upper surface of the main body 1802 of the second support member 18.
The shaft portion 3204 is supported by a bearing portion provided on the mounting piece 3202 so as to be movable in the vertical direction and not to be removed.
The pressing portion 3206 has a pressing surface 3210 that is provided at the upper end of the shaft portion 3204 and can elastically contact the back surface of the multilayer glass panel 2.
The compression coil spring 3208 is interposed between the attachment piece 3202 and the pressing portion 3206, and always urges the pressing portion 3206 in a protruding direction.
The maximum protrusion position of the pressing portion 3206 is determined by a stopper provided on the shaft portion 3204 coming into contact with the attachment piece 3202.
At this maximum protruding position, the pressing surface 3210 is positioned above the cutting edges of the third and fourth cutters 24 and 26, and the pressing edge 3210 is pressed before the cutting edges of the third and fourth cutters 24 and 26 come into contact with the glazing channel 4. The surface 3210 is configured to elastically contact the back surface of the multilayer glass panel 2.
Further, when viewed from the thickness direction of the multilayer glass panel 2, the location of the first pressing member 30 elastically contacting the front surface matches the location of the second pressing member 32 elastically contacting the back surface.

The moving mechanism 19 moves the first support member 16 and the second support member 18 from the outside to the inside of the outline of the multilayer glass panel 2, and moves the first support member 16 and the second support member 18 to at least one of the first support member 16 and the second support member 18. A contact member 34 is provided which contacts the edge of the laminated glass panel 2 and positions the first support member 16 and the second support member 18 with respect to the edge.
More specifically, the abutting member 34 positions the first to fourth cutters 20, 22, 24, 26 with respect to the edge by contacting the edge of the multilayer glass panel 2.
In the present embodiment, as shown in FIGS. 1 and 3, the positioning member 34 has a rectangular plate shape and projects from the upper surface of the main body 1802 of the second support member 18.

The guide mechanism 40 follows the swing of the first and second arms 12 and 14 and moves in a direction in which they are separated from each other while maintaining the parallel state of the first and second support members 16 and 18.
In the present embodiment, the guide mechanism 40 includes a guide plate 4002, a guide groove 4004, and two guide pins 4006.
As shown in FIGS. 2 and 3, the guide plate 4002 has an elongated plate shape.
The guide plate 4002 is arranged with its longitudinal direction facing the direction in which the first and second support members 16 and 18 face each other, and one end of the guide plate 4002 in the longitudinal direction is connected to the first support member 16 via a bolt 4010 and a nut 4012. The main body 1602 is attached.
A guide groove 4004 is linearly formed along the longitudinal direction of the guide plate 4002 at the other end in the longitudinal direction of the guide plate 4002.
Two guide pins 4006 project from the main body 1802 of the second support member 18, and the two guide pins 4006 are inserted through the guide grooves 4004.
Therefore, each guide pin 4006 is guided by the guide groove 4004, so that the second support member 18 moves in a direction approaching and separating from the first support member 16 while maintaining a parallel state.

Next, the usage method of the glazing channel cutting apparatus 10 of this Embodiment is demonstrated.
It is assumed that a multi-layer glass panel 2 in which glazing channels 4 are formed on the front and back surfaces of the peripheral portion is prepared in advance and is held in a state where the multi-layer glass panel 2 extends horizontally by a jig (not shown). .
The first and second support members 16 and 18 are brought close to the peripheral edge of the multi-layer glass panel 2 in a state where the tip portions 1206 and 1406 of the first and second arms 12 and 14 are opened, and the first and second support members 16 are moved. , 18, the peripheral edge of the multilayer glass panel 2 is positioned.
3 and 4, the contact member 34 is applied to the edge of the multilayer glass panel 2, and the pressing surface 3210 of the second pressing member 32 is applied to the back surface of the multilayer glass panel 2.
In this state, the cutting edges of the third and fourth cutters 24 and 26 are located at a position away from the glazing channel 4.
Then, the glazing channel cutting device 10 is connected to the peripheral portion of the multilayer glass panel 2 in a state where the contact member 34 is applied to the edge of the multilayer glass panel 2 and the pressing surface 3210 of the second pressing member 32 is applied to the back surface. The glazing channel cutting device 10 is positioned so that the cutting edges of the first to fourth cutters 20, 22, 24, and 26 face the location of the glazing channel 4 to be cut.

When the cutting edges of the first to fourth cutters 20, 22, 24, and 26 reach the location of the glazing channel 4 to be cut, the first and second arms 12 and 14 are moved in the closing direction.
Then, first, the multilayer glass panel 2 is sandwiched between the pressing surfaces 3010 and 3210 of the first and second pressing members 30 and 32.
Eventually, the first to fourth cutters 20, 22, 24, and 26 come into contact with the glazing channel 4 in a state where the multilayer glass panel 2 is sandwiched between the pressing surfaces 3010 and 3210, and as shown in FIG. 1 and the movement of the second arms 12 and 14, the cutting edges of the first to fourth cutters 20, 22, 24 and 26 come into contact with the front and back surfaces of the multilayer glass panel 2, and the glazing channel 4 is cut. .
The glazing channel 4 is softened and cut by the first to fourth cutters 20, 22, 24, 26 heated by the heater 28 as described above.

When the glazing channel 4 is cut, the portion of the cut glazing channel 4 is taken out (FIG. 6B), and a molded part 6 of the glazing channel having a dimension corresponding to the cut portion is fitted into the cut portion (FIG. 6). (C)).
Thereby, the application | coating operation | work of the glazing channel 4 to the multilayer glass panel 2 is complete | finished.

  As described above, according to this embodiment, the glazing channel 4 can be cut mechanically and automatically, and the glazing channel 4 can be cut accurately and easily. This is advantageous for improvement.

It is a front view of the glazing channel cutting device 10 in this Embodiment. 2 is a rear view of the glazing channel cutting device 10. FIG. 1 is a side view of a glazing channel cutting device 10. FIG. It is operation | movement explanatory drawing of the glazing channel cutting device. It is operation | movement explanatory drawing of the glazing channel cutting device. (A) thru | or (C) are explanatory drawings of the application | coating operation | work of the glazing channel 4 to the multilayer glass panel 2. FIG.

Explanation of symbols

  2 ... Multi-layer glass panel, 4 ... Glazing channel, 10 ... Glazing channel cutting device, 16 ... First support member, 18 ... Second support member, 19 ... Moving mechanism, 20 ... First cutter , 22 ... 2nd cutter, 24 ... 3rd cutter, 26 ... 4th cutter, 28 ... heater.

Claims (5)

A glazing channel cutting device for cutting glazing channels applied to the peripheral portions of the front and back surfaces forming both surfaces in the thickness direction of a multilayer glass panel at two points spaced in the extending direction of the glazing channels,
A first support member arranged to face the surface of the multilayer glass panel;
A second support member arranged to face the back surface of the multilayer glass panel;
The first support member is moved toward and away from the front surface, and the second support member is brought into and out of contact with the back surface in conjunction with the contact and separation of the first support member with respect to the front surface. A moving mechanism that moves in the direction;
A thin plate-like first cutter and a second cutter that are supported parallel to each other at a distance from each other on the first support member and abut against the surface at right angles by approaching the surface of the first support member;
A thin plate-like third cutter and a fourth cutter that are supported parallel to each other by the second support member and are in contact with the back surface at a right angle by the approach of the second support member to the back surface;
A heater for heating the first to fourth cutters;
A glazing channel cutting device comprising: When viewed from the thickness direction of the multi-layer glass panel, the location of the first cutter that contacts the front surface matches the location of the third cutter that contacts the back surface, and The location of the second cutter in contact with the front surface is coincident with the location of the fourth cutter in contact with the back surface,
The glazing channel cutting device according to claim 1, wherein The first supporting member is provided with a first pressing member that can be elastically contacted with a portion of the surface of the multilayer glass panel on which the glazing channel is not applied,
The second support member is provided with a second pressing member that can be elastically contacted with a portion of the back surface of the multilayer glass panel to which the glazing channel is not applied,
The multi-layer before approaching the front and back surfaces of the first and second cutters and the third and fourth cutters when approaching the front and back surfaces of the first and second support members The glass panel is sandwiched between the first pressing member and the second pressing member.
The glazing channel cutting device according to claim 1, further comprising: When viewed from the thickness direction of the multi-layer glass panel, the location of the first pressing member elastically contacted with the front surface and the location of the second pressing member elastically contacted with the back surface match.
The glazing channel cutting device according to claim 3. The moving mechanism moves the first supporting member and the second supporting member from the outside to the inside of the outline of the multilayer glass panel,
At least one of the first support member and the second support member is a contact member that contacts the edge of the multilayer glass panel and positions the first support member and the second support member with respect to the edge. Is provided,
The glazing channel cutting device according to claim 1, wherein

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