SE531998C2 - Lock with plunger - Google Patents

Description

Prior art In order to reduce the forces that need to be applied to the accessory in panic situations, it is previously known to design the plunger rotatable relative to the bang, about an axis of rotation perpendicular to the axial displacement of the plunger and the bale. - direction. To prevent the door from opening from the outside, the rotational movement of the drop piston can be selectively blocked and allowed, by means of a locking device which is operated with the emergency or panic evacuation accessory. When the door is pressed outwards and the accessory is activated, the catch of the drop piston is released so that the drop piston can be rotated in the direction away from the end plate, whereby the friction between them decreases. This reduces the force required to release the piston from the engagement with the end plate.

DE 102 07 630 A1 describes a lock with a drop which is axially displaceable together with a drop carrier and rotatable relative to the drop carrier. The lock also comprises an electrically operable locking device with which the rotational movement of the falls relative to the fall carrier can be locked or allowed. The construction shown in DE 102 07 630 A1 comprises a number of levers, which makes it relatively complicated and space-consuming.

Furthermore, the device described therein means that all or a relatively large part of the force with which the end plate is pressed against the drop piston is transferred to the part of the locking device where the release of the rotational movement of the falls is to be effected. Thereby there is a risk that a relatively large force, transmitted from the final plate, causes a high friction between the parts of the locking device, whereby the force required to release the locking device becomes large.

EP 1 291 478 A1 describes another lock with a drop piston which is axially displaceable together with a bang and rotatable relative thereto. A locking device for selectively releasing and blocking the rotational movement of the drop piston comprises a bearing roller which is arranged on a pivot arm and which in contact with two different surfaces on a linearly displaceable part of the locking device can selectively allow and prevent linear displacement of this part. to thereby allow and prevent rotation of the plunger, respectively. This device is also relatively space-consuming and complicated. Although the use of a rotating roller contributes to reducing the friction in the locking device, it also increases the need for space as well as the device's complexity and material as well as manufacturing cost.

Brief Description of the Invention An object of the present invention is therefore to provide a lock with an improved device for selectively allowing and preventing rotation of a drop piston relative to a bange which is axially movable together with the drop piston.

Another object is to provide such a lock which requires small maneuvering forces to release the drop piston for rotation even when a large force on the door leaf presses the drop piston into abutment against the end plate.

Another object is to provide such a lock which is space-saving. Yet another object is to provide such a lock in which the drop piston, the banger and the locking device can be designed as a modular unit for easy assembly in a modularized lock manufacturing system. Yet another object is to provide such a lock which can be provided relatively inexpensively and with simple structural parts. 10 l5 20 25 30 J? Lu now! LB t fi Im These and other objects are obtained with a lock of the kind stated in the preamble of claim 1 and which exhibits the features stated in the characterizing part of the claim. The lock is intended for doors, windows and the like and especially for outwardly openable escape doors which are on their inside are provided with emergency or panic escape accessories for operating the lock.

The lock comprises a locking post, a drop piston with a bange and a locking device. The drop piston and the bang are together axially displaceable relative to the locking post. The drop piston is fixed to the bang, rotatable about an axis of rotation which is substantially perpendicular to the axial displacement direction of the fall piston and the bang. The locking device is adjustable between a release position in which rotation of the drop piston about the axis of rotation is allowed and a locking position in which the position of the drop piston relative to the bang is fixed. According to the invention, the locking device comprises a first and a second linearly displaceable element and at least two pairs of cooperating sliding surfaces, which sliding surfaces are arranged on the drop piston, the first displaceable element and the second displaceable element, respectively, and designed to transmit a rotational movement of the piston to respective linear displacement movements of the first and second displaceable elements.

The invention is based on the insight that it is possible to prevent self-locking of the locking device for the rotation of the drop piston, by reducing the force transmitted from the drop piston to the parts of the locking device when the door is pressed outwards and the end plate exerts a force on the drop piston. With the two linearly movable elements and the two pairs of cooperating sliding surfaces for transmitting the force from the end plate via the drop piston and the two displaceable elements, it is possible to provide a two-stage gear in which the transmitted force is reduced in two steps. By designing the cooperating sliding surfaces at a suitable angle in relation to the direction of movement of each moving part, it is possible to adapt the gear ratio, ie. the power reduction for each gear step. In the locked position, the force is transmitted from the end plate via the drop piston and the two displaceable elements to an adjustable locking member, which in turn transmits the force to the lock housing. Due to the force reduction achieved by then both pairs of cooperating sliding surfaces, the force with which the second displaceable element is in contact with the locking member will be small. This prevents these two elements from self-locking to each other, which otherwise leads to a greater force being required to switch the locking member from its locking position to its release position. The invention thus reduces the force required to release the locking device when the door is pressed outwards at the time of opening. This in turn helps to reduce the force that must be applied to an accessory connected to the lock in order to open the door, for example, in an emergency situation when it is pressed outwards with great force. In other words, the force-reducing pairs of cooperating sliding surfaces according to the invention enable a better control over the forces transmitted from the end plate into the lock when the door is pressed outwards with the drop piston in engagement with the end plate.

The sliding surfaces cooperating in pairs can be designed in different ways, as long as their design entails a reduction of the force in the direction of movement which is transmitted between them. For example, the sliding surfaces can consist of flat, single-curved or double-curved surfaces. The one pair of cooperating sliding surfaces, which during rotation of the drop piston transmits the force from the drop piston to the first linearly displaceable element, is suitably formed with a concave and a convex single-curved surface, respectively. The second pair of cooperating sliding surfaces suitably comprises a conical surface arranged on the first linearly displaceable element and a flat surface arranged on the second linearly displaceable element. The directions of movement of the first and second linearly displaceable elements are suitably arranged perpendicular to each other and the conical surface as well as the flat surface are suitably formed at an angle of about 60 ° and 30 °, respectively, to the direction of movement of the respective elements.

With the power and motion transmission thus obtained, the constituent components can be made very small. The first and second displaceable elements are then suitably accommodated in the bang. This results in a very compact and space-saving device.

The locking device suitably comprises an operating rudder which can be actuated by an emergency evacuation accessory, a panic evacuation accessory or the like for switching between a locking position, in which movement of the second displaceable element is prevented and a release position, in which linear movement of the second displaceable element is allowed.

In this case, the locking device suitably comprises a pivotable flap which is arranged between the second displaceable element and a locking arm fixed to the operating rudder.

The lock suitably comprises a base plate in which the bar is steered received for axial displacement and at which the operating rudder is rotatably fixed. The base plate, the plunger with the bang and the locking device thus suitably form a modular unit which can easily be mounted on a post unit included in the lock. 10 15 20 25 531 HÉS The module unit suitably also comprises an interlocking case and an interlocking locking device which are movably arranged at the base plate.

Additional objects and advantages of the lock according to the invention will become apparent from the following detailed description and from the appended claims.

Brief description of the figures In the following, exemplary embodiments of the invention will be described with reference to the figures, of which: Fig. 1 is an exploded view of a lock according to an embodiment of the invention.

Figs. 2a-c are a perspective view from behind, a side view and a front perspective view, respectively, of a post unit included in the lock shown in Fig. 1.

Fig. 3 is a perspective view of a module unit included in the lock shown in Fig. 1.

Fig. 4 is an exploded view of the mold unit shown in Fig. 3. Figs. 5a and 5b are schematic plan views from below, partly in section of certain parts of the module unit shown in Fig. 3.

Figs. 6a-e are principle sketches of certain parts included in the module unit shown in Fig. 3 and show these parts when they occupy different positions.

Detailed description of embodiments The embodiment of the lock according to the invention shown in the figures comprises a number of modules included in a modular system. The module system also includes other modules that can 10 15 20 25 30 EE? This is combined with the modules shown in the figures to provide other functions of the lock.

Referring to Fig. 1, the lock comprises a post unit 10 which forms the mounting base for the lock. The post unit 10 comprises a locking post 11 and a mounting beam 12 with a U-shaped cross-sectional profile, which is fixed to the post and which has two mounting plates 13, 14 projecting parallel backwards from the post (see also Fig. 2a). At the post unit, a cylinder rudder module 20, a space rudder module 30 and a pressure rudder module 40 are arranged. These can be operated in the usual way by means of a locking cylinder, an evacuation accessory, such as an emergency evacuation accessory or a panic evacuation accessory, or a pressure (not shown) via traditional means (not shown) which are accommodated in central openings in the respective rowers.

In the case of a post unit, a hook piston module 50 as well as two plates 61, 62, which together form a locking box and which form the top and bottom of the box, respectively, are fixed. The various modules of the lock (10, 20, 30, 40, 50, 61, 62) are held together in the usual way by screws and socket nuts.

As can most clearly be seen from Fig. 2b, a drop piston module 100 is further arranged at the post unit 10 and fixed to it by means of a pin 101 which extends through corresponding openings in the mounting plates 13, 14.

The piston module 100 is shown in more detail in Figures 3 and 4 and its components will now be described. The drop piston module 100 comprises a base plate 110, a drop piston 120, a bange 130, an operating rudder 140 and a locking drop 150. The drop piston 120 is rotatably fixed to the bungee 130 by means of a shaft pin 131 which is received in corresponding through openings in the drop piston and the bangs. The bungee 130 is guided so as to be occupied between opposite guide surfaces 111, 112 of the base plate 110. The bungee 130 and the drop piston 120 fixed thereto can thus be displaced rectilinearly relative to the base plate 110 and thus relative to that of the post unit 10 and the plates 61, 62 formed the lock housing. Figure 1 shows the drop piston 120 and the bungee 130 in an extended position.

The interlocking cases 150 are axially displaceable and guided in the uptake by the base plate 110, between guide surfaces 113, 114.

The movement of the interlocking case 150 is controlled by a pivotable locking device 151 which is rotatably fixed to the base plate 110 and a spring 152, which communicate via a ball 153 with a shaft 160 received in the bang 130. The function of the interlocking case is not described in more detail here.

The drop piston 120 has a front portion 121 arranged on one side of the shaft pin 131 with two symmetrically arranged inclined drop surfaces 122, 123 arranged symmetrically with the shaft pin 131 in relation to a central plane. This portion 124 has a sliding surface 125. This sliding surface has a single curved portion 125a and a flat portion 125b.

A first axially displaceable element in the form of an axle pin 160 is accommodated in the bang 130, a parallel, parallel to the direction of movement of the bang. More specifically, the shaft pin 160 is axially displaceably received in a circular-cylindrical first race 133 which is arranged in a portion of the bead 130 distal to the plunger 120. The shaft pin 160 has a front portion 161 with a larger cross-sectional diameter and a rear portion 162 with a smaller cross-sectional diameter. The two portions are joined by an intermediate conical portion with a cone angle of about 60 °. This conical portion forms a rear sliding surface 163 on the shaft pin 160. The flange 133 correspondingly has a front portion 134 of larger diameter and a rear portion 135 of smaller diameter for receiving with a narrow fit the front of the shaft pin 160. 161 and rear 162 lots respectively.

At the end of the front portion 161 of the shaft journal 160 facing the drop piston 120, a single curved front sliding surface 164 is provided.

The radius of curvature of this sliding surface 164 substantially corresponds to the radius of curvature of the single curved portion 125a of the sliding surface 125 of the drop piston 120. A compression spring 166 is received in the rear portion 135 of the first bore 133 and in a rearwardly opening circular cylindrical recess 167 in the rear portion 160 of the shaft journal 160. The compression spring 166 thus presses the shaft pin 160 in the direction of the drop piston 120.

The bungee 130 also has a second bore 136 which extends perpendicularly to the front portion 134 of the first barrel 134 and which opens at a side surface of the banger 130. locking plate 170. A stop pin 137 is fixed to the bead 130 so that it projects into the second bore to prevent the locking plate 170 from being extended out of the bore 136 through the mouth at the side surface of the banger. The barrier plate 170 has two opposite side surfaces 171, 172 which are parallel to the direction of movement of the barrier plate and which in contact with the corresponding walls of the second barrel 136 control the movement of the barrier plate. At the end of the barrier plate facing the first bore 133, a flat end surface 173 is provided. The locking plate further has a sliding surface 174 which is arranged as a flat side surface, which connects the surfaces 171 and 173. The flat sliding surface 174 has an angle of about 30 ° to the axial direction of movement of the locking plate and thus to the side surfaces 171, 172. The locking plate 170 also has another end surface 173 opposite and with this 10 15 20 25 30 531 99% ll parallel abutment surface 175. The abutment surface 175 is connected to the side surface 171 by an inclined connecting surface 176.

The base plate 110 comprises a wing-shaped portion 115 at which a first seat 116 for the rotatable operating rudder 140 is arranged. A second seat 117 which receives a pivotable locking flap 180 is also provided at the wing-shaped portion 115. The operating rudder 140 is rotatably fixed to the first seat 116 and has a radially projecting operating arm 141 and a radially projecting locking arm 142, with which the locking flap 180 can be actuated. .

The control rudder 140 can be driven to, according to the figures clockwise, rotation by means of a carrier 41 (see Fig. 1) which abuts the control arm 141 and which is connected to the pressure rudder module 40. The pressure rudder module 40 is further connected to the evacuation rudder module 30 and the cylinder rudder module 20. in the opening direction of the respective rudders in these modules thus causes the operating rudder 140 to be turned clockwise towards a release position.

The locking device for selectively preventing and allowing rotation of the plunger 120 about the shaft 131 includes the rear portion 124 of the plunger, the shaft pin 160, the compression spring 166, the locking plate 170, the locking flap 180 and the operating rudder 170. The shaft pin 160 element. The shaft pin 160 and the locking plate 170 are displaceable in respective directions of movement which are defined by the first 133 and the second 136 races, which races are perpendicular to each other. The locking device further comprises two pairs of cooperating sliding surfaces. The first pair of sliding surfaces consists of the sliding surface 125 on the rear portion of the drop piston 120 and the front sliding surface 164 on the front portion 161 of the shaft journal. .

With reference to Figs. Sa-b and 6a-e, the function of the lock will now be described. In the position shown in Fig. 6a, the drop piston 120 and the bungee 130 are in their extended position. This position corresponds to the position of the piston 120 shown in Figs. 1, 3 and 5a. .

The tumbler side 123 of the drop piston 120 abuts against the end plate.

As shown in Fig. 5a, the tumbler side 123 is substantially parallel to the door leaf. The single-curved portion l25a of the sliding surface 125 of the sliding surface 125 abuts the front sliding surface 164 of the shaft pin 160. The rear sliding surface 163 of the shaft pin 160 abuts the sliding surface 173 of the locking plate 170. abutment surface 181 against an end surface 143 of the locking arm 142 of the operating rudder 140. The operating rudder 140 is in its locking position, the abutment of the locking arm 142 against the locking flap 180 preventing rotation of the locking flap. This also prevents the locking plate 170 and the shaft pin 160 from being displaced, the drop piston 120 being prevented from rotating about the shaft 131.

The locking device is thus in its locking position.

When the door is to be opened quickly, for example in an emergency or panic situation, to allow evacuation through the door, a person presses the emergency or panic evacuation accessory which is connected to the evacuation rudder in the evacuation rudder module 30.

The evacuation rudder is then caused to rotate and this rotational movement is transmitted in the usual manner to the carrier 41.

The driver 41 in turn acts on the operating rudder 140 so that it rotates clockwise according to the figures. The rudder 140 then assumes the position shown in Fig. 6b. As shown in the figure, the end surface 143 of the locking arm 142 of the rudder 140 has been moved away from its locking abutment against the abutment surface 181 of the locking flap 180, so that the locking flap has rotated clockwise to the position shown in Fig. 6b. The locking plate 170 is thereby free to be displaced outwards in the direction of the operating rudder in the barrel 136. In the example shown in Fig. 6b, the locking plate has undergone this displacement under the influence of gravity. This can happen, for example, if the operating rudder 140 is caused to rotate without any force being applied to the tumbler side 123 of the drop piston 120. Normally, however, such a force is present on the tumbler side 123, the shaft pin 160 being displaced to the right and the piston 120 being rotated as soon as . Thus, when the lock plate 170 is released, the shaft pin 160 is free to displace to the right in the first barrel 133 and the drop piston 120 is free to rotate about the shaft 131 in the direction indicated by the arrow in Fig. 5b.

By, in the position of the locking device shown in Fig. 6b, applying a force outwards on the door leaf, the end plate will act with a force on the tumbler side 123 of the drop piston 120.

The drop piston is then allowed to rotate about the shaft 131 and by the contact between the sliding surfaces 125 and 164 to press the shaft pin inwards, to the right, in the bore 133. The shaft pin 160 is released from the extended locking plate 170 and only the relatively small force from the compression spring 166 must be overcome. allow rotation of the drop piston 120. Fig. 6c shows the position of the parts of the locking device when the drop piston 120 has performed a part of its rotation.

In this position, the tumbler side 123 of the drop piston 120 has been tilted relative to the end plate. If the force on the door leaf remains, the force exerted by the end plate on the drop piston will partly cause the drop piston 120 together with the bang 130 to be displaced linearly relative to the base plate 110 in the inward direction (to the right in the figures) and partly to bring the drop piston 120 to complete its rotation about the axis 131.

During this rotation, the flat portion 125b of the sliding surface 125 of the drop piston abuts against the front sliding surface 164 of the shaft pin 160. The shaft pin is thereby displaced further inwards in the bore 133. The parts of the locking device then assume the positions shown in Fig. 6d.

If the force on the door leaf remains, the end plate will finally press the drop piston 120 and the bang 130 to the fully retracted position shown in Fig. 6d. The drop piston 120 is thus released from the end plate and the door can be opened.

As can be seen from the above description, it is thus possible to open the door very simply by only pressing the evacuation accessory and at the same time pushing the door outwards.

If a force in the outward direction is applied to the door leaf when the locking device is in the locking position shown in Fig. 6a for the rotation of the drop piston, the end plate will exert a force on the drop piston, which force is parallel to the normal direction of the tumbler side 123. This force tends to rotate the plunger 120 about the axis 131 in the direction of the arrow shown in Fig. 5b.

The force is transmitted by the lever action about the shaft 131 to the contact surface between the sliding surface 1225a of the drop piston and the front sliding surface 164 of the shaft pin. The direction of rotation of the drop piston 120 is non-parallel therefore, the respective contact surface of the drop piston 120 and the shaft pin 160 are formed as sliding surfaces 125, 164 which allow these surfaces to slide relative to each other. Furthermore, in order to cause a displacement of the shaft journal 160, the contact surface between them during the entire displacement of the shaft journal 160 must have an angle to the axial direction of movement of the shaft journal, which angle cannot be perpendicular to or parallel to the axial direction of movement of the shaft journal. Due to this angle between the contact surface and the direction of movement of the shaft journal 160, the force component transmitted from the piston to the shaft journal which is parallel to the direction of movement of the shaft journal becomes less than the total force exerted by the piston on the shaft journal. Other force components transmitted on the shaft journal are taken up by the bungee 130 and transmitted to the base plate 110. Thereby a reduction of the force which is transmitted via the shaft journal further from the drop piston 120 towards the locking plate 170 and then on to the contact surface between the operating rudder 140 locking arm 142 and the locking flap 180.

Correspondingly, the contact surface between the rear sliding surface 163 of the shaft journal 160 and the sliding surface 174 of the locking plate 170 has an angle which is not perpendicular to or parallel to the direction of movement of the locking plate controlled by the second bore 136. As a result, the force component which is passed on by the locking plate 170 to the locking flap 180 will also be less than the force with which the shaft pin 160 acts on the locking plate 170. Other force components transmitted on the locking plate 170 are taken up by the bang 130 and transferred to the base plate 110 160 and the locking plate 170 thus provide a further reduction of the force transmitted from the end plate to the contact surface between the locking flap 180 and the locking arm 142 of the operating rudder 140.

The lock according to the invention thus achieves a two-stage force reduction of the force transmitted from the end plate to the contact surface between the locking flap 180 and the actuating arm 142 of the rower when the door is pressed outwards in closed position.

This force reduction is significant because it leads to a reduced friction between the locking arm 142 and the locking flap 180 when the operating rudder 140 is to be rotated to its release position to allow rotation of the drop piston 120 about the shaft 131. The reduced friction in turn leads to only a small force the actuator rudder 140 needs to be fitted to turn it to its release position even when very large forces push the door outwards in the closed position.

This also reduces the force required on the evacuation accessory to release the drop piston and thereby enable the door to be opened and evacuated through it. Thus, even if, for example, a crowd in an emergency or panic situation is pressed against the door, it is sufficient to apply a small force to the emergency or panic evacuation accessory to open the door and allow evacuation. The invention further contributes to the fact that the European safety requirements imposed on evacuation doors regarding the maximum required maneuvering force on the accessory in relation to the force applied to the door leaf can be met.

An exemplary embodiment of the invention has been described above. It is understood that the description is not limiting of the invention but that it may be varied freely within the scope of the appended claims. For example, the pairs of cooperating sliding surfaces can be designed with other geometries than those described above. The sliding surfaces can, for example, be flat, symmetrically single-curved, symmetrically double-curved or curved in other ways. A specific example is that at least one pair of cooperating sliding surfaces comprises a convex spherical sliding surface arranged on a ball and a concave spherical sliding surface arranged on a movable element. In order to achieve the desired reduction of the force transmitted from one to the other of the elements provided with sliding surfaces, the contact surface 10 15 Ü? J: fi ß KE 3 17 between the two sliding surfaces must be designed at a certain angle in relation to the direction of movement of at least one element. In each pair of sliding surfaces, if the elements are formed in softer materials, it may be appropriate for the shape of the two cooperating sliding surfaces to correspond to each other geometrically.

Thereby a larger contact surface is created between them, whereby the contact pressure decreases to a corresponding degree.

Furthermore, an embodiment is described above with two axially displaceable elements provided with sliding surfaces. It will be appreciated that the lock may comprise more than two such displaceable elements and that such an alternative embodiment may further reduce the force transmitted from the locking plate to the contact surface of the locking device where release of the locking device is effected by bringing two abutment surfaces out of contact with each other.

It will also be appreciated that, instead of being provided with a plunger and a hook bolt, the lock may comprise, for example, only one plunger, two plungers or any other combination of pistons and bolts where at least one plunger is included. Furthermore, of course, the number and type of rowers or other means for operating the lock can be freely chosen.

Claims (8)

10 15 20 25 30 hå L) .l ... a É: Q ulf * Krav A lock, for doors windows and the like comprising a locking post (10), a drop piston (120) with a bange (130) or a locking device, at which lock; the drop piston and the bang are together axially displaceable relative to the locking post, - the drop piston is fixed to the bang, rotatable about an axis of rotation (131) which is substantially perpendicular to the axial displacement direction of the drop piston and the bang and - the locking device is adjustable between a release position about the axis of rotation is allowed and a locking position in which the position of the drop piston relative to the bang is fixed, characterized in that the locking device comprises a first (160) and a second (170) linearly displaceable element and at least two pairs of cooperating sliding surfaces (125: 164, 163, 174 ), which sliding surfaces are arranged on the plunger, the first displaceable element and the second displaceable element, respectively, and designed to transmit a rotational movement of the plunger to the respective linear displacement movements of the first and the second displaceable element. A lock according to claim 1, wherein the first pair of cooperating sliding surfaces comprises a curved first surface (125) arranged on the drop piston (120) and a curved second surface (164) arranged on the first displaceable element (160). A lock according to any one of claims 1 or 2, wherein the second pair of sliding surfaces comprises a conical first surface (163) arranged on the first displaceable element (160) and a flat second surface (174) arranged on the second displaceable element ( 170). 10 15 20 Lock according to one of Claims 1 to 3, in which the first (160) and second (170) displaceable elements are accommodated in the bang (130). A lock according to any one of claims 1-4, wherein the locking device comprises an operating rudder (140) which is actuated by an evacuation accessory or the like for switching between a locking position, in which movement of the second displaceable element (170) is prevented and a release position, in which linear movement of the second displaceable element is allowed. A lock according to claim 5, wherein the locking device comprises a pivotable locking flap (180) arranged between the second displaceable element (170) and a locking arm (142) fixed to the operating rudder (140). A read according to any one of claims 5-6, comprising a base plate (110) in which the bar (130) is steered received for axial displacement and in which the operating rudder (140) is rotatably fixed, the base plate (110), the drop piston (120) with the bang (130) and the locking device constitute a modular unit (100) mountable at a post unit (10) included in the lock. A lock according to claim 7, wherein the module unit comprises an interlock case (150) and an interlock locking device (151) movably mounted at the base plate (110).