LT5569B - Heat activated device of fire door for unwarped blocking in a casing - Google Patents

Abstract

The invention relates to devices for fire door, particularly to heat activated device of fire door for unwarped blocking in a casing, which can be used for blocking doors in fire. New is that after going heat activated locks off the door is not onlyblocked over all perimeter in door opening but also is pressed to a casing. For that purpose conical parts of fixing plugs of door locks are placed in corresponding holes of a casting, which are centrifugally moved with regard to central longitudinal axis of heat activated locks, in a door closing direction at x distance, which in common case is equal to a high of a seal strips between a door leaf and a casing.

Description

The invention relates to fire door devices, and more particularly to a heat-activated fire door locking device for blocking a door in a door opening in the event of a fire.

As is known, the purpose of using a fire door is to close the doorway securely and tightly in the event of a fire, thus preventing the spread of fire and smoke from one room to another and limiting air entry into the fire area. Such doors have special requirements depending on their use: they must meet a certain fire resistance class to ensure a reliable fire barrier for a certain period of time. Most fire and commercial doors used in commercial and residential buildings are constructed with a metal frame covered with sheet metal sheets with heat and sound insulation between them. As a standard, such doors are fitted to the frame with hinges and a lock.

The main and fundamental disadvantage of such fire doors is that their sash is distorted when exposed to high temperatures. This is due to the fact that the metal sheet of the heated door leaf side expands, while the opposite side of the door leaf, which is not exposed to temperature, does not change its dimension. As a result, the door leaf folds out, forming a gap in the middle of the sash (if the door in the room where the fire originated opens inside) or the top and bottom of the sash (if the door opens outwards). In this way, the door loses its airtightness and opens the way for air to enter the fire compartment and the spread of heat, smoke and fire to adjacent compartments.

U.S. Pat. 5121950 solves this problem by installing additional heat-activated locks on the door leaf, which consist of a spring mounted inside the cylindrical body and a pin sealed by a thermosetting closure. In the event of a fire, these shutters melt, the pins "shoot" from the door leaf into the specially made slots or openings in the door jamb and lock the door leaf in the jamb.

A lock for a door locking frame described in U.S. Pat. 5121950, has two drawbacks: first, the use of such heat-activated locks is provided only on the side of the door hinges, although, as practice shows, the opposite side of the door leaf is most deformed during a fire. Secondly, and most importantly, the lock pin has a diameter of only 60-80% of the size of the socket or opening in the jamb, so even after these security locks are triggered, there is a gap between the door leaf and the jamb. Even a small gap between two fire zones is dangerous because of the special temperature regime at this place, where there is a constant supply of oxygen, with very high temperature rise and deformation, which is very difficult to stop. Emerging and widening gaps between the sash and frame open the way for smoke and heat to spread.

It is an object of the present invention to provide a fire door locking device in the jamb which, once activated, reliably and tightly locks the door across the perimeter of the door leaf, and secondly, continuously and actively presses the door leaf to the jamb. between door leaf and frame.

For this purpose, heat-activated locks of the present invention are installed in possible locations of deformation of the door leaf during fire. Each lock consists of an elongated bushing with a cylindrical locking pin having a tapered front and a push spring which presses the cylindrical end of the pin. The outer end of the bushing, which coincides with the edge of the door leaf, is closed by a cover made of thermoplastic material. The threaded hole in the cylindrical part of the plug has a screw securing it in the longitudinal direction of the bushing, which is inserted through a hole in the opposite end of the bushing.

The heat-activated locks are mounted in the sash so that the end of the shutter, closed with a thermoplastic cover, is flush with the edge of the door leaf.

The holes in the frames, which coincide with the locks of the fire door locks in the sash, are made into holes which, in the event of a fire, are pressed by the springs and are "fired" by the locking pins as the movement blocking caps melt. The diameter of the holes in the door frame shall not exceed the diameter of the cylindrical part of the locking pin.

In the fire door locking device of the present invention, unlike in the prior art, the holes in the door frame are made not coaxially but centrally with respect to the central longitudinal axes of the respective latch locks, i.e. the openings in the frame are constructed such that there is a distance x between the fire door lock sleeve and the central longitudinal axes of the corresponding hole in the frame. In practice, this means that the opening in the frame is pulled at a distance x in the direction of closing the door leaf. This is done so that in the event of a fire, the tapered part of the locking pin activated, the springs being pushed deep into the hole in the jamb, actively presses the sash against the door jamb, preventing any gap between them.

The invention will now be described in more detail with reference to the accompanying drawings, in which:

Fig. 1 is a schematic general view of a fire door with locks mounted in accordance with the present invention;

Fig. 2 is a detailed cross-sectional view of a non-activated fire door unit;

Fig. 3 is a detailed cross-sectional view of an activated fire door assembly;

Figures 4-6 are schematic views illustrating the operation of the fire door locking device of the present invention in the frame.

Fig. 1 is a schematic diagram of a fire door with locks mounted in accordance with the present invention. It should be noted that this particular embodiment of the invention relates to a door system in which both the sash and the frame are made of metal, but other but also other refractory materials may be used. The door leaf is designated by the numeral 1 and the door frame by the numeral 2. As shown in this drawing, the heat-activated locks 3 are mounted inside the door leaf 1 at its perimeter edge. The number of locks 3 can be varied depending on the size of the door, fire resistance class and room purpose.

FIG. 1 line A-A image. The lock 3 of the present invention has an elongated cylindrical sleeve 4, preferably made of metal, with outer and outer threads 5 and 6 on its outer open end and a press spring 8 on the opposite end of its inner closed sleeve 4. and a steel locking pin 9 consisting of a cylindrical portion 9a and a tapered portion at the top 9b. The diameter of the cylindrical part 9a of the locking pin 9 is slightly smaller than the inside diameter of the bushing 4, the size of this tolerance is not essential, it is important that the pin 9 does not slip inside the bushing 4.

The cylindrical portion 9a of the pin 9 has a threaded opening 10 in which a longitudinally extending screw 11 of the pin 9 is screwed through a hole 7 in the bushing 4 and passing through the inside of the spring 8. The screw 11 is screwed into the threaded hole 10 so that the pin 9 can extend outwardly through the open end of the bushing 4 not more than the length of the conical portion 9b. The bolt 11 also serves a protective function: it prevents the pin from being fired outward when the door is open and injuring a person standing next to it, causing the protective cover 12 to be broken.

The open outer end of the sleeve 4 is closed by a thermoplastic cap 12 screwed into the inner thread 6 of the sleeve 4. The cap 12 retains the pin 9 which is pushed outward by the compression spring 8. The inner side of the cap 12 facing the inside of the sleeve 4 and keep coaxial with the other components of the shutter 3.

As mentioned above, the cap 12 is made of a thermoplastic material which melts when the temperature reaches about 200 ° C in the room. Suitable thermosetting materials include polypropylene, polyethylene, polystyrene and the like.

The assembled lock 3 is screwed into the threaded opening in the edge 13 of the door leaf 1 formed by the inwardly flanged flanges 14. The lock 3 is screwed into the opening in the door leaf through the outside of the door edge 13. The lock 3 is screwed into the door leaf so that the protective cover 12 is flush with the surface 13 of the door leaf edge.

As can be seen in Fig. 2, the door frame 2 has a hole 15 in front of the lock 3 for entering the conical portion 9b of the locking pin 9. The diameter of the orifice 15 is preferably equal to the diameter of the cylindrical portion 9a of the pin 9. The hole 15 is made centrally with respect to the longitudinal axis 16 of the lock 3, i.e. when the door 1 is normally closed, the central axis 17 of the hole 15 is pulled in the direction of the door closing at a distance x which is practically equal to the height of the sealing strips 18 and 19.

Figure 3 is a detailed view of the device 2 of the activated door leaf 1 of the present invention in cross-section through the device shown in Figure 3; 1 line A-A image.

When the temperature in the fire room exceeds the melting point of the protective covers 12, the latter melt and the pin 9 tapers 9b, pushed by the springs 8, "fires" in the direction of arrow B into the hole 15, thereby blocking the door leaf 1 in frame 2.

As mentioned above, the opening 15 of the frame 2 is not coaxial to the lock 3, but is pulled to the side of the door closure at a distance x which is at most equal to the height of the sealing strips 18 and 19. For this reason, the conical portion 9b of the pin 9, pushed by the spring 8 and supported by the surface of the conical portion 9b, presses the door leaf 1 in the direction of arrow C to the frame 2 on the edge of the centrifugal hole 15 The conical portion 9b transforms the longitudinal movement of the pin 9 into the transverse movement of the door leaf 1 in its closing direction C. If before the fire the distance between the door leaf 1 and the jamb 2 is 3 mm, then later, after the fire and the locks 3 bore 15, presses the door leaf 1 against the frame 2, reducing the distance between them by 1 mm. The distances given here are for illustration purposes only and may be different depending on the design of the door system.

Fig. 4-6 illustrates schematically, step by step, the principle of operation of the fire door door leaf blocking frame 1 of the present invention during a fire. Fig. 4 illustrates the position of the devices when the temperature in the room does not exceed the limit above which the locking caps 12 melt. This position corresponds to the position detailed above with reference to Fig. 2. In this position, the springs 8 of the locks 3 are compressed and press the pins 9 at the maximum force, which are retained inside the lock 3 by protective thermoplastic teeth 12.

Fig. 5 is a schematic representation of a situation where the temperature in the room has exceeded the melting point of the protective covers 12. As the covers 12 melt, the pins 9, push springs 8, "shoot" in the direction of the arrows B and enter the frame holes 15. Since the hole 15 is made in the frame 2 centrifugally with respect to the longitudinal axis of the lock 3 and the pin 9 is pulled down 15 and, on the basis of the conical surface to the edge of the hole 15, pushes the door leaf 1 in the direction of arrow C toward the frame 2.

Figure 6 is a schematic representation of the final position of the fire door locking frame in the frame, corresponding to the position detailed with reference to Figure 3. In this position, the pins 9 of the locks 3 are maximally inserted into the openings 15 of the frame, and the door leaf 1 is pressed against the frame 2 and locked in this position. If the gap between the door leaf 1 and the door frame 2 was 3 mm before the fire, the door leaf 1 was pressed against the door 2 by reducing the gap between the door leaf 1 and the door 2 by the protective door locking system of the present invention.

The heat-activated fire door locking system in the frame of the present invention provides a reliable and non-deformable door sash press against the frame. Once activated, the locks 3 reliably block the door opening along its entire perimeter and continuously and actively press the door leaf 4 against the frame 2, preventing any gap between them.

Claims (1)

DEFINITION OF INVENTION 1. A fire door non-deformable locking frame during fire in a unit comprising a plurality of heat-activated sash locking frame locks in the sash having an elongated one-end open cylindrical body, an internally mounted compression spring and a locking pin, a thermocouple lid and a locking latch closure. and a pin inside the housing and openings in the housing, characterized in that each heat-activated lock 3 consists of a) Cylindrical sleeve (4) with inner and outer threads (5) and (6) at the open end and a hole (7) at the opposite closed end, the sleeve (4) being screwed into the threaded opening at the door edge (13) formed by flanges (14); b) a locking pin (9) slidably inserted inside the cylindrical sleeve (4) consisting of a cylindrical part (9a) having a threaded opening (10) and a conical part (9b); c) pressure springs (8) inserted inside the sleeve (4) between the cylindrical part (9a) of the pin (9) and the closed end of the sleeve (4); d) a screw (11) inserted through the opening (7) of the sleeve (4) and screwed into the threaded opening (10) of the cylindrical part (9a) of the pin (9), limiting the length of the movement of the pin (9) in the longitudinal direction; e) a thermoplastic cap (12) having a melting point of 150-200 ° C screwed into the inner thread (5) of the open end of the sleeve (4) and the spring and pin (9) compressed inside the sleeve; and in that the frame (2) has a plurality of holes (15) of a diameter not larger than the diameter of the cylindrical portion (9a) of the pin (9), making each door lock (3) centrifugal toward the door closing side such that 3) and the central longitudinal axes (16) and (17) of the aperture (15) have a distance (x) not greater than the height of the sealing strips (18, 19).