FR3097585A1 - wooden sash window door device with non-standard dimensions up to 6.25 m2, able to carry triple glazing and fitted with closing frames in the same plane - Google Patents

Abstract

Wooden sash window door device of non-standard dimension up to 6.25 m2, capable of carrying triple glazing and fitted with closing frames in the same plane according to the principle of a wall within the opening (d) , which are determined according to its dimension - A particular kinematics of the opening according to a principle of limiting the bending forces over the height of the opening by reducing the tilting angle according to a three-phase opening process, - A counterweight and safety system (r) by cables (s) and blocker (t), adapted according to the inertias of the moving masses, characterized in that the cables (s) are placed on either side and hidden in the frame, allow load balancing for effortless handling, glass moving according to a guillotine kinematics, and responding to a heat transfer coefficient value of 1.2 W / m2 K for thicknesses of 68mm or 0, 8 W / m2 K for thicknesses of 100mm characterized by : - A wooden structure (a) for the constitution of the blank constituting the opening and the frame by a tri-ply assembly (b) - An assembly of the standard structure which is however characterized by mechanical reinforcements (c) Figure for the abbreviated [Fig. 1]

Description

wooden guillotine door window device of non-standard size up to 6.25 m2, able to carry triple glazing and equipped with closing frames in the same plane

The invention relates to a wooden sash window door device of non-standard size up to 6.25 m2, capable of carrying triple glazing and equipped with closing frames in the same plane according to the principle of a glass wall. moving according to a guillotine kinematics, and responding to a value of the heat transfer coefficient of 1.2 W/m² K for thicknesses of 68mm or 0.8 W/m² K for thicknesses of 100mm

State of knowledge : It is first important to recall the principle of French windows which are the closest technologies on the functional level. These French doors are governed by two types of technologies known historically:
- French-style French doors, according to the principle of one or more leaves which open by rotation of the sash on the frame using rotating axes placed in a pivot connection between the sash and the sleeper. The limit of this technology, apart from the fact that the opening is limited by weight by the load capacity of the pivots, is that this technology violates the release of the bay window by multiple uprights (vertical) which distorts the opening (vision, passage) ,
- French windows opened by slide, which can themselves be distinguished according to several technologies: the first covering of one element on the other (the most common) which infringes the clearance over half the length of the door window, the second by brick partition where the sliding assemblies are inserted into the wall but disrupt the thermal resistance of the wall due to the clearances necessary for the position of the elements in the wall in the open position.

Out of window door technology, there are sash windows, which act kinematically by vertical sliding of the sash on another fixed pane placed above this first. The principle is that the sliding takes place on another plane. Several sliding technologies are known based on two principles: the first of a vertical sliding where the sash is placed continuously on a plane distinct from the frame and slides parallel to the latter. This technology, the simplest, is today thwarted by the normative requirements in terms of thermal resistance due to the need for an operating clearance between the planes which constrains the thermal performance. Another known technology consists in introducing a kinematics capable of ensuring relative movement on two distinct planes to end up in the closed position with windows placed in a single plane. This second technology calls for the introduction of rail connections on the uprights of the opening and fixed frames so as to ensure an angular clearance of the window which then moves vertically. This technology meets the normative requirements on the thermal panel since in the closed position, the window is flat against the frame in the presence of insulating joints.

Whatever the known technologies relating to sash windows, these are however dimensionally constrained due to the displacement load which cannot exceed 150 kg (mechanical resistance) for the most advanced technologies (example: industrial “Hawa”).

As a result of the purpose of a sash window device incorporating perfect thermal insulation, this requires the integration of triple glazing technology. Indeed, it is useful to recall the average index established according to the technologies: Glazing 4/12/4 = ug 2.4; Glazing 4/16/4 = ug 1.8; Glazing 4/16/4 under gas (argon type) = ug 1.3; Triple glazing = ug 0.6 to 0.8; Insulated wall according to RT 2012 standards = ug0.3.

This integration of triple glazing constrains the moving load and amplifies the mechanical stresses accordingly, which disturbs the permitted glazing surface accordingly.

Consequently, in the state of knowledge, the technology of sash windows did not allow it to be introduced into a window door principle because of the mechanical constraints resulting from this technology and the thermal requirements to be obtained.

Presentation of the invention: the invention relates to a wooden sash window door device of non-standard size up to 6.25 m2, capable of carrying triple glazing and equipped with closing frames in the same plane according to the principle of a glass wall moving according to a guillotine kinematics, and responding to a value of the heat transfer coefficient of 1.2 W/m² K for thicknesses of 68mm or 0.8 W/m² K for thicknesses of 100mm characterized by:

- A wooden structure (a) for the constitution of the square constituting the opening and the frame:
= Either a tri-ply assembly (b) of wood species made up in the thickness of a first 23mm ply with a pine species placed on the outer part of the opening and which allows low heat transfer, a second thickness of 23 mm in oak capable of ensuring the mechanical resistance of the opening, and a third thickness of 22 mm in oak contributing both to the mechanical resistance and to the reduction of the heat transfer between the inside and the center of the plaice,
= either a three-ply assembly (b) made up of a unique kind of wood species in larch but whose fibers are oriented in an opposite direction so that the central ply places its fibers in the horizontal direction, this to allow the bending load recovery on the central part of the square while it is a question of accentuating the insulation on the exteriors,

- An assembly of the standard structure which is however characterized by mechanical reinforcements (c) within the opening (d), which are determined according to its size; that is :
= for glazing from 0 to 150 kg: no reinforcement necessary on the lower crosspiece,
= for glazing weighing 150 to 250 kg: a steel reinforcement (c) responding to a quadratic moment of 3000 mm4 is placed longitudinally inside the crosspiece (e) and over its entire length, with an overhang (f) of the said reinforcement allowing it to be fixed on the vertical uprights (g) of the opening, this in order to limit the bending of the crosspiece (e) and also to take up the shear forces located at the junction (h) of the vertical parts and horizontals of the sash (d),
= for glazing weighing 250 to 350 kg: this steel reinforcement (c) inside the crosspiece is produced according to the same principle of integration throughout the length of the lower crosspiece and of overtaking, differing however in that the quadratic moment is 4500 mm4 while two other reinforcements (i) are integrated into the vertical uprights of the opening and are made integral (j) with the reinforcement of the lower crosspiece (e),

- A particular kinematics of the opening according to a principle of limitation of the bending forces on the height of the opening by reducing the angle of tilting according to a process of opening in three phases:
= a first movement (k) the upper part of the sash (l) in order to release it from the frame by tilting through an angle of a maximum of 3 degrees around an axis located on the lower part of the sash opening (m),
= A second movement (n) in the continuity of the first allows the rapid vertical repositioning of the entire sash (d) thanks to a rail slope (o) placed in the frame in the lower part and on which the part slides lower part of the sash (m), thanks to guides (p) placed laterally on the latter (d), thus allowing the entire sash (d) to rise while being constrained by the rails (o) and guides (p),
= A third movement (q) along the vertical of the sash (d) on a separate plane from the frame.

- A counterweight and safety system (r) by cables (s) and blocker (t), adapted according to the inertias of the moving masses, characterized in that the cables (s) are placed on either side and concealed in the frame, allow load balancing for effortless handling,

- the blocker (t) acts as a parachute acting by gravity and detecting the presence of tensile forces on the cables (s) of the counterweight system (r); in the event of breakage or blockage causing the release of one of the cables (s), the ascender (t) undergoes an imbalance of forces which modifies its position and comes to block the movement by friction and bracing on the structure of the upright of the frame thus preventing any descent.

Figures :
perspective view of the device
sectional view of counterweight and safety system placed in the carpentry
sequenced view of the three positions of the kinematics
Glossary :
a) wooden structure
b) three-ply assembly
c) mechanical steel reinforcement
d) opening
e) lower transom of the sash
f) protrusion of the mechanical reinforcement
g) vertical jambs of the sash
h) junction of the vertical and horizontal parts of the sash
i) other reinforcements
j) junction of vertical and horizontal reinforcements
k) first movement
l) upper part of the sash
m) lower part of the sash
n) second movement
o) rail slope
p) guides placed laterally on the frame
q) third movement
r) counterweight system
s) cables
t) blocker

Claims (1)

Wooden guillotine door window device of non-standard size up to 6.25 m2, able to carry triple glazing and equipped with closing frames in the same plane according to the principle of a glass wall moving according to a guillotine kinematics, and corresponding to a value of the heat transfer coefficient of 1.2 W/m² K for thicknesses of 68mm or 0.8 W/m² K for thicknesses of 100mm characterized by:

- A wooden structure (a) for the constitution of the square constituting the opening and the frame:
= Either a three-ply assembly (b) of wood species made up in the thickness of a first 23mm ply with a pine wood species placed on the outer part of the opening and which allows low heat transfer, a second thickness of 23 mm in oak capable of ensuring the mechanical resistance of the opening, and a third thickness of 22 mm in oak contributing both to the mechanical resistance and to the reduction of the heat transfer between the inside and the center of the plaice,
= either a three-ply assembly (b) made up of a unique kind of wood species in larch but whose fibers are oriented in an opposite direction so that the central ply places its fibers in the horizontal direction, this to allow the bending load recovery on the central part of the square while it is a question of accentuating the insulation on the outsides,

- An assembly of the standard structure which is however characterized by mechanical reinforcements (c) within the opening (d), which are determined according to its size; that is :
= for glazing from 0 to 150 kg: no reinforcement necessary on the lower crosspiece,
= for glazing weighing 150 to 250 kg: a steel reinforcement (c) responding to a quadratic moment of 3000 mm4 is placed longitudinally inside the crosspiece (e) and over its entire length, with an overhang (f) of the said reinforcement allowing it to be fixed on the vertical uprights (g) of the opening, this in order to limit the bending of the crosspiece (e) and also to take up the shear forces located at the junction (h) of the vertical parts and horizontals of the sash (d),
= for glazing weighing 250 to 350 kg: this steel reinforcement (c) inside the crosspiece is produced according to the same principle of integration throughout the length of the lower crosspiece and of overtaking, differing however in that the quadratic moment is 4500 mm4 while two other reinforcements (i) are integrated into the vertical uprights of the opening and are attached (j) to the reinforcement of the lower crosspiece (e),

- A particular kinematics of the opening according to a principle of limitation of the bending forces on the height of the opening by reducing the angle of tilting according to a process of opening in three phases:
= a first movement (k) the upper part of the sash (l) in order to release it from the frame by tilting through an angle of a maximum of 3 degrees around an axis located on the lower part of the sash opening (m),
= A second movement (n) in the continuity of the first allows the rapid vertical repositioning of the entire sash (d) thanks to a rail slope (o) placed in the frame in the lower part and on which the part slides lower part of the sash (m), thanks to guides (p) placed laterally on the latter (d), thus allowing the entire sash (d) to rise while being constrained by the rails (o) and guides (p),
= A third movement (q) along the vertical of the sash (d) on a separate plane from the frame.

- A counterweight and safety system (r) by cables (s) and blocker (t), adapted according to the inertias of the moving masses, characterized in that the cables (s) are placed on either side and concealed in the frame, allow load balancing for effortless handling,

- the blocker (t) acts as a parachute acting by gravity and detecting the presence of tensile forces on the cables (s) of the counterweight system (r); in the event of breakage or blockage causing the release of one of the cables (s), the ascender (t) undergoes an imbalance of forces which modifies its position and comes to block the movement by friction and bracing on the structure of the upright of the frame thus preventing any descent.