RU2426848C2 - Device for windows or doors - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: device comprises a support body, a handle and a polyhedron. The support body is designed for fixation on a door or a window. The handle is installed on a support body or in it without possibility of displacement in axial direction, but also with the possibility of rotation. A polyhedron serves for mechanical engagement of the device with the mechanism integrated into a door or window. At the same time the polyhedron protrudes with a section of polyhedron beyond the support body, and also the engagement system formed between the handle and the polyhedron to transfer torque from the handle to the polyhedron and to lock its transfer from the polyhedron to the handle. Length of a polyhedron section protruding beyond the support body and inserted into a frame of a door or a window as the support body is inserted into a door or a window is adjusted automatically. The polyhedron passes in the engagement system with the possibility of displacement in longitudinal direction, but without the possibility of slippage, and enters through it into the handle. The engagement system has two grips provided between the handle and the polyhedron, which at the specified gap along the angle of rotation between the gripping surfaces are engaged to each other with a force and/or geometric closure so that the possibility is provided to send a movement to a polyhedron, which accompanies the handle actuation. The device includes the first grip, which is connected to the handle without the possibility of slippage, and there is the second grip, which receives the polyhedron without the possibility of slippage, but with the possibility of displacement in longitudinal direction.

EFFECT: invention makes it possible, when installing onto a window or a door, to automatically take into account thickness of a frame or a profile with preservation of its safety and protection function with the purpose of always reliable engagement with the mechanism integrated into a door or a window.

17 cl, 6 dwg

Description

The invention relates to a device for windows or doors according to the restrictive part of paragraph 1 of the claims.

Such a device, known from EP 1121501 B1, has a thrust body for mounting on a window or on a door, and a control element in the form of a handle that is mounted on the supporting body without the possibility of movement in the axial direction, but with the possibility of rotation. The tetrahedral rod connected to the handle without the possibility of rotation passes through the supporting body and serves to actuate the locking mechanism. A clutch system is provided between the handle and the tetrahedral rod, by means of which torque is transmitted from the handle to the tetrahedral rod, but the transmission of movement from the tetrahedral rod to the handle is prevented. Thus, you can open the window or door at any time from the inside using the handle. However, on the contrary, for example, the movement transmitted through a window or door mechanism to the tetrahedral rod is blocked so that the handle connected to the tetrahedral rod remains stationary in case of manipulation of the mechanism. Such a device protects against hacking.

The device disclosed in EP 1121501 B1 with numerous structural elements and components has a relatively complex structure, which leads to high installation costs and high manufacturing costs. In addition, it does not take into account that windows and doors have different frame and profile thicknesses, so that the distances between the abutment surface for the abutment body of the device and the mechanism integrated into the window or door are different. Therefore, depending on the design of the window or door, devices with differently long tetrahedral rods are needed. However, since the length of the portion of the tetrahedral rod protruding beyond the abutment body is strictly specified, it is necessary to install a suitable tetrahedral rod at the factory or in place to ensure reliable operation of the mechanism using the device. This requires both the manufacturer and the consumer increased storage costs, since it is necessary to keep many tetrahedral rods of various lengths in stock. In addition, there is a danger of incorrect selection of the rod, which can lead to a negative impact on the perfect operation of the device or the window, or the door.

The objective of the invention is to eliminate these and other disadvantages of the prior art and the creation of a window or door device, which is made economically by simple means and is easy to use. In particular, when installing on a window or door, the various thickness of the frame or profile should be automatically taken into account while maintaining its safety and protection functions with the goal of always reliable coupling with the mechanism integrated into the window or door.

The main features of the invention are given in the characterizing part of paragraph 1 of the claims. Embodiments are the subject of claims 2-20.

In a window or door device for actuating an integrated mechanism in a window or door containing a thrust body that is intended to be mounted on a window or door, a handle that is mounted on the thrust body without being able to move in the axial direction, but with the possibility of rotation, a polyhedron for mechanical engagement of the device with a mechanism integrated into the window or door, the polyhedron acting as a polyhedron portion behind the thrust body, and the coupling system made between the handle and the polyhedron for According to the invention, the transmission of torque from the handle to the polyhedron and the blocking of the transmission from the polyhedron to the handle, it is provided that the length of the polyhedron portion protruding beyond the stop body and the window or door inserted into the frame of the window or door is automatically set, the polyhedron being guided with the possibility of longitudinal movement, but also without the possibility turning in the clutch system and passes through it all the way to the handle.

Thus, the polyhedron guided in the clutch system with the possibility of longitudinal movement, but without the possibility of rotation, is automatically coordinated when installing the device with the thickness of the frame or profile of the window or door without the need to have a supply of polyhedral rods of various lengths, which must be selected and installed accordingly. Thus, the handling of the device is greatly simplified. There is no longer any need for storing multiple tetrahedrons of different lengths. In addition, it is ensured that the polyhedron always engages accurately with a window or door mechanism so that the window or door can be reliably actuated. Operating reliability is clearly increasing. Errors during installation are effectively prevented, in particular by the installer in place. At the same time, the clutch system made between the handle and the polyhedron provides protection against unauthorized entry from the outside, since its function is fully preserved.

The polyhedron is guided inside the clutch system with the possibility of movement along the axis of rotation of the handle for a limited course of movement and movement in the longitudinal direction against the force of the spring. The spring pushes the polyhedron preferably constantly outward so that it can confidently and reliably enter the window or door mechanism. At the same time, the spring is compressed if the shaft is too long, and during installation, it is pushed back into the handle through the clutch system. In this case, the polyhedron is expediently supported through a compression spring inside the handle.

In order that the spring loaded polyhedron could not fall out of the clutch system, respectively from the thrust body, the movement of the polyhedron inside the clutch system is limited by at least one stop. Thus, the polyhedron is retained within the clutch system. Thus, it cannot be lost.

In order to achieve optimal regulation of the corresponding necessary length of the polyhedron portion protruding from the thrust body, the polyhedron has at least one other stop that defines the depth of the polyhedron entering the mechanism integrated into the window or door. Due to this, the end portion of the polyhedron can always fully enter, for example, into the internal socket, but without exiting through it from the end and without stopping into the window profile. Thus, collisions with the frame or profile of a window or door are effectively eliminated.

In another important embodiment, the clutch system has two grips provided between the handle and the polyhedron, which, for a given clearance in the angle of rotation between the gripping surfaces, can engage with each other with a force closure and / or with a geometric closure so that the accompanying actuation The crank movement can be transmitted to a polyhedron. In this case, a first grip is provided, which is connected without the possibility of turning with the handle, while the second grip receives a polyhedron without the possibility of rotation and with the possibility of moving in the longitudinal direction.

To prevent unauthorized actuation of the handle, respectively, of the window or door mechanism from the outside through the polyhedron, the clutch system has at least one locking link provided between the grippers and the thrust body, which is designed and / or located so that the torque acting on the handle can be transmitted on the polyhedron, however, the torque acting on the polyhedron stops or blocks the movement of the polyhedron, respectively, the actuation of the integrated into the window o or door mechanism. To this end, between each locking link and the second grip, it is provided that a frictional, geometric and / or force short circuit is provided, wherein each locking link can be displaced and / or actuated by means of functional surfaces or side surfaces formed on the grippers.

In addition, according to the invention, it is provided that each locking link is loaded with a spring and is made in the form of a cylindrical body or ball, while corresponding to the locking links there are provided locking recesses inside the locking body.

Due to such a clutch system, the device acts as a mechanical diode, i.e. actuation of the window or door mechanism with the handle is always possible, while unauthorized permutation movement directly on the polyhedron is prevented by locking links, since they are pressed with a force, geometric or frictional closure when turning the second grip, connected without the possibility of turning with the polyhedron retaining grooves in a persistent body. In this case, the gap between the grips provided by the angle of rotation is important. It ensures that when the handle is rotated, the locking links are extended by the functional surfaces or lateral surfaces of the first connected without the possibility of turning with the gripping handle from the locking recesses in the thrust body, before the functional surfaces or side surfaces of the second connected without the possibility of turning with the gripping polyhedron can press the locking elements into retaining recesses. Conversely, it is ensured that when the polyhedron is actuated and the second grip connected to it without the possibility of turning, the locking links are pressed into the locking grooves before the first grip can squeeze them out. Thus, the device in a simple manner provides a high degree of protection. Additional locking cylinders or other locking elements are not required.

Preferably, at least two locking recesses correspond to each locking link, so that the locking action of the clutch system can also be effective if desired also at different angular positions of the handle. Therefore, the locking recesses are expediently located in the thrust body with uniform angular distances.

In another important embodiment of the invention, it is provided that the locking recesses are made in the insert body, which is installed with a force and / or geometrical closure in the thrust body. In addition, the clutch system is housed in a plug-in body as a kind of housing. To do this, it has a recess in which the grips are mounted pivotally concentrically to the axis of rotation of the handle. Thus, the insertion body forms not only a rotary support for the grippers, but also a counter support for the locking links. Thus, it fixes the grips and locking links and thereby the entire clutch system in the thrust body so that a simple and compact structure is formed that can be manufactured quickly and economically and is easy to handle.

To ensure accurate and reliable achievement by the handle of its predetermined window or door functional positions, it is possible to fix the first grip with fixing means in at least one characteristic functional position of the handle and / or mechanism integrated into the window or door. In this case, the fixing means are formed on the stubborn body. Upon reaching at least one characteristic position, they enter the corresponding locking recesses in the first grip.

Structurally, it is preferable if the locking means are made in one piece with the thrust body. Due to this, the design and installation are greatly simplified. This is also facilitated by the fact that the locking links and locking means are located along the axis of rotation of the handle, respectively, of the polyhedron in different planes. This provides, in particular, the possibility of a modified, in particular material-saving, implementation of the gripping elements, which also contributes to cost reduction. At the same time, high stability is achieved, so that the device can easily withstand increased loads.

Other features, details and advantages of the invention follow from the claims, as well as the following description of exemplary embodiments with reference to the accompanying drawings, in which:

figure 1 is a partial section of a window or door device according to the invention, in isometric view;

figure 2 - the device according to figure 1, in the first exploded isometric view;

figure 3 - the device according to figure 1, in a second exploded isometric view;

figure 4 - the thrust body shown in figure 1 of the device, in a bottom view, partially in the lumen;

5 is a persistent body according to figure 4 after actuating the handle, a bottom view, partially in the lumen;

6 is a persistent body according to figure 4 after unauthorized activation of the polyhedron, a bottom view, partially in the lumen.

Designated as a whole in figure 1, the position 1 device is made in the form of a window device. It has a handle 6, which is supported by the neck 7 of the handle without axial movement and rotatable on the thrust body 4. To actuate the mechanism integrated into the window (not shown), a polyhedron 8 is provided, which is preferably made in the form of a tetrahedral rod. It acts as a multifaceted section 8a for the thrust body 4 for entering with a geometric closure with its free end 8d into the window mechanism, in particular into the internal socket provided therein (also not shown). The clutch system 10 provided between the handle 6 and the polyhedron 8 is configured to transmit torque from the handle 6 to the polyhedron 8, however, the transmission from the polyhedron 8 to the handle 6 is blocked, thereby preventing unauthorized opening of the window by actuating the polyhedron or window mechanism.

The thrust body 4 is made in the form of a socket, which with screws 16 is mounted on a sash (not shown). Located between the neck 7 of the handle and the body 4 of the socket with the possibility of rotation, the cover 14 can be raised against the action of the compression spring 20 relative to the lower side of the neck of the handle. In the mounted state of the device 1, it closes the body 4 of the outlet and the screws 16 from the outside. For installation, the cover 14 can be rotated on the body 4 of the outlet, a cylindrical neck portion 22 is formed centrally above the passage opening 24 (see FIG. 2), which with a small gap enters the central recess 13 of the cover 14. A compression spring 20 surrounds the neck portion 22 and holds in place fixed on the edge with the body 4 of the socket cover 14.

To accommodate the screws 16 in the body 4, the sockets are made symmetrically on both sides of the passage opening 24, two screw holes 26, which, as shown in Fig. 3, end on the rear side in the pins 15. They protrude into the recess 21, which is made on the rear side in the body there are 4 sockets and serves for placement with power and geometric closure of the plug-in body 50.

The plug-in body 50 has a coaxial to the holes 26 for screws, respectively, to the pins 15 in the body 4 of the socket at the edges of the two grooves 58, which are placed with a geometric closure of the pin 15 of the body 4 of the socket. The through hole 51 in the insertion body 50 lies concentrically to the central passageway 24 of the body 4 of the socket and thereby also concentrically rotates the axis D of the handle 6. The hole 51 expands inside the insertion body 50 into a circular recess 151, which, as shown in FIG. 2, is provided with circumference with several radial recesses having the shape of segments 52. The recess 151 serves to accommodate the clutch system 10, made between the handle 6 and the tetrahedron 8, in particular two grippers 28, 42 of the clutch system 10 as pivot bearings. The recesses 52 are located on both sides of the bore 51 symmetrically and at equal angular distances. On the rear side, in the pins 56 formed to the insert body 50, holes 26 of the body 4 of the socket for screws 16 continue and the body 4 of the socket is aligned when mounting the device 1 on a window frame that is equipped with corresponding holes.

As shown in FIG. 1, the plug-in body 50 forms a lower end for the socket body 4. In accordance with this, the insertion body ends flush with its bottom side with the bottom side of the socket body 4, with the exception of pins 56. To fix the insertion body 50, recesses 104 are provided inside the recess 21 of the socket body 4, which capture the corresponding the fixing edges 55 on the insertion body 50. The dismounting recesses 57 on the edge of the recess 21 shown in FIG. 4 serve to install a tool to enable the removal of the insertion body 50 from the body 4 of the socket, if necessary. .

As shown further in FIG. 4, grooves 124 are provided at the edges between the bridges 114 in a preferably made plastic body 4 of the socket. They lead to the formation of ribs on the body 4 of the socket, which saves material and at the same time increases the rigidity of the body.

In order to ensure that the tetrahedral rod 8, regardless of the thickness of the window profile frame, with its free end 8d, is always completely in the internal socket of the window mechanism, the length L of the protruding body 4 and the polyhedral portion 8a introduced into the window frame when installing the resistant body 4 on the window is automatically installed. For this, the tetrahedral rod 8 is guided with the possibility of shear in the longitudinal direction against the force of the spring and without the possibility of turning in the clutch system 10, but with the possibility of shear, respectively, permutation with a limited course of the HH movement along the rotary axis D of the handle 6. The spring force acting on the tetrahedral rod 8 created by a coil spring 18, which is installed in a blind hole 5 in the handle 6. Directed with the possibility of sliding in the clutch system 10, the tetrahedral rod 8 is constantly loaded due to this, along the D axis in the direction of the window, respectively, in the direction of the closing mechanism. It passes through the clutch system 10 and enters in the opposite direction into the blind hole 5 of the handle 6.

In order that the tetrahedral rod 8 could not fall out of the handle 6, respectively, from the clutch system 10, its travel HH is limited in the direction of the window by an emphasis 8b. It is preferably formed on a tetrahedral rod 8, for example, in the form of a simple notch that is pressed or stamped into the longitudinal edge of the rod 8. However, it is also possible to arrange the pin or pin on the side or diagonally of the tetrahedral rod 8, for example, by welding or soldering. It is important that the stop 8b lies between the clutch system 10 and the handle 6 so that the spring 18 can extrude the shear tetrahedral rod 8 outward until the stop 8b abuts the clutch system 10. Inside, the stroke VN of the movement of the tetrahedral rod 8 is limited by the depth of the blind hole 5 and the size of the spring 18.

The free end 8d of the tetrahedral rod 8 carries another stop 8c, which can also be in the form of a notch or a depression. This stop 8c is oriented so that the tetrahedral rod 8 can enter deep enough into the internal socket of the window mechanism, however, it does not pass through it enough to abut the other side of the window profile. Another emphasis 8c therefore sets the depth of entry of the polyhedral portion 8a protruding beyond the body 4 of the socket. In addition, it ensures that each tetrahedron 8 always enters with the same length into the internal socket so that optimal transmission of force is always guaranteed.

At the same time, the stop 8c together with the spring 18 in the neck 7 of the handle provide automatic matching of the length L of the socket protruding beyond the body 4 of the socket 4a. If the tetrahedral rod 8 is too long for the existing window profile, then the tetrahedral portion 8a first enters with its free end 8d so far into the inner socket until the abutment 8c abuts against it. Then the tetrahedral rod 8 is shifted back against the action of the spring 18 in the neck 7 of the handle 6 so far until the body 4 of the outlet is adjacent to the window.

The total length of the tetrahedral rod 8 and its stroke VN displacement are coordinated with each other so that the device 1 can be mounted on a variety of windows with different frame thicknesses. Thus, there is no need to replace the tetrahedral rod 8 with a longer or shorter tetrahedral rod. There is also no need to store rods of various lengths or at a fitter in the warehouse, which significantly reduces logistics and installation costs.

Along with the automatic adjustment of the length L of the tetrahedral rod 8 with different thicknesses of the frame or door leaf, the clutch system 10 between the handle 6 and the tetrahedral rod 8 provides increased protection against burglary, since it is made so that the window, respectively integrated mechanism can be actuated only from the inside using the handle 6, but not from the outside via a tetrahedral rod 8. For this, the polyhedron 8 is mounted with the possibility of movement in the longitudinal direction and without the possibility of rotation in the clutch system 10, which has two grippers 28, 42. In addition, locking links 38 are located between the grippers 28, 42 and the body 4 of the socket. Together with the clutch elements 28, 42, they provide the possibility of transferring the torque acting on the handle 6 to the polyhedron 8 However, the torque acting on the polyhedron 8 stops or blocks the movement of the polyhedron, respectively, the actuation of the window or the mechanism integrated into the window.

The first grip 28 forms a grip of the handle. It is made in the form of a sleeve and connected without the possibility of rotation with the handle 6. It has a central bore 281 and a flange section 282, which is inserted with a small gap into the circular recess 121 in the body 4 of the socket (see Fig. 3). A smaller diameter shaft 283 adjoins the flange section 282, which surrounds the neck collar 9 of the handle 6 through the through hole 24 and the neck section 22 of the socket body 4. The neck collar 9 is located centrally relative to the pivot axis D on the lower side of the neck 7 of the handle and forms on the end side access to blind hole 5 of handle 6.

The outer perimeter of the cervical collar 9 does not form a cylindrical surface, but in accordance with the inner surface of the neck shaft 283, respectively, with the inner wall of the passage bore 281, a multifaceted surface, so that the sleeve 28 mounted on the neck flange 9 is connected without rotation with the handle 6. Fixation in axial the direction of the sleeve 28 on the handle 6 is carried out using the flanging BR due to the fact that the outer edge of the cervical collar 9 inside the sleeve 28 is bent outward. For this, the bore 281 in the sleeve 28 is provided on the inner perimeter with a step or step 284.

An annular recess 71 is formed around the neck collar 9 in the neck 7 of the handle. It receives both the neck portion 22 of the socket body 4 and the compression spring 20, so that they are not visible from the outside, and the lower side of the neck 7 of the handle lies only a short distance above the cover plate fourteen.

In total, four fixing recesses 134 for fixing means 34 are located on the outer perimeter of the flange section 282 with an angular distance of 90 ° from each other. The fixing means 34 are formed in the body 4 of the socket on the spring jumpers 234, which lie symmetrically on both sides of the recess 121 for the flange section 282. Using both fixing means 34, which are preferably made integrally with spring jumpers 234 and body 4 of the socket, the window handle 6 is fixed in four characteristic functional positions. ia, preferably in the closing position, the opening position (right or left) and the tilted position of the window, while in each functional position both locking means 34 enter simultaneously into two opposing locking recesses 134. Thus, the handle grip 28 acts as a locking sleeve. Due to this, the user can always easily recognize functional positions. In this way, improper window control is prevented. Other locking positions are possible due to the implementation of other locking recesses 134 in the flange section 282, for example at angular distances of 45 ° from each other. In this case, both locking means 134, upon reaching the characteristic functional position, also enter into two opposite locking recesses 134 in the first grip 28, which positions the handle accordingly.

On the side opposite the shaft 283, the flange portion 282 carries four protrusions 285, which as engagement elements are engaged with the two grips 42 of the clutch system 10. They, as shown in figure 4, are located symmetrically to the rotary axis D, while two protrusions 285 lie to the right and left of the longitudinal axis L of the body 4 of the socket. In addition, they are made L-shaped in cross section, which, on the one hand, saves material and, on the other hand, provides high stability and loadability.

The outer surfaces (not shown) of the protrusions 285 are cylindrical in accordance with the flange portion 282, while the outer diameter of the flange portion 282 and protrusions 285 corresponds, with the exception of a small clearance of movement, to the inner diameter of the recess 121 in the body 4 of the socket and the recess 151 in the insert body 50 Due to this, the gripper 28 of the handle is precisely guided and supported with the possibility of rotation both in the recess 121 in the body 4 of the socket and in the recess 151 of the plug-in body 50 lying in accordance with it.

In addition, as shown in Fig. 4, the protrusions 285 have circumferential functional surfaces 128, 228. Opposite the longitudinal axis LA of the body 4 of the outlet 4, the surface 128 of the protrusions 285 form gripping surfaces that, for a given clearance angle B, are engaged with the corresponding gripping surfaces the surfaces 142 of the second grip 42. In contrast, the rosette surfaces 228 facing the longitudinal axis LA of the body 4 form functional surfaces or side surfaces that interact with the locking links 38 clutch system 10.

The second grip 42 forms a polyhedron grip. It has a washer-like base plate 421, which is provided on both sides to save material with two cutouts 422. In the center, the main plate 421 has a neck portion 423, which in the center is provided with a tetrahedral recess 424 for placement with a geometric closure and with the possibility of longitudinally shifting the tetrahedral rod 8 .

In addition, the main plate 421 carries four protrusions 425 at the edges, which as engagement elements are engaged with a grip 28 of the handle of the clutch system 10. They are located, as shown in figure 4, symmetrically with respect to the rotary axis D, with two protrusions 425 lying to the left and right relative to the longitudinal axis LA of the body 4 of the socket. In addition, they are made L-shaped in cross section, which, on the one hand, saves material and, on the other hand, provides high stability and loadability.

The outer surfaces (not shown) of the protrusions 425 are cylindrical in accordance with the main plate 241, while the outer diameter of the main plate 241 and the protrusions 425 corresponds, with the exception of a small clearance of movement, to the inner diameter of the recess 151 in the insert body 50. Due to this, the polyhedron grip 42 together with the grip 28 of the handle precisely guides and rests with the possibility of rotation in the recess 151 of the insert body 50, while the flange section 282 of the grip 28 of the handle is guided inside the recess 121 of the body 4 of the socket in a separate loskosti.

Just as the protrusions 285 of the gripper 28 of the handle, the protrusions 425 of the gripper 42 of the polyhedron have circumferential functional surfaces 142. They face the longitudinal axis LA of the body 4 of the socket. They form gripping surfaces, which at a given clearance B of the angle of rotation come into engagement with the gripping surfaces 128 of the gripper 28 of the handle.

The main plate 421 carries four other protrusions 426, which are arranged in pairs on both sides of the longitudinal axis LA of the body 4 of the outlet approximately V-shaped. Between each pair of protrusions 426, a socket 427 is formed parallel to the longitudinal axis LA, in which a spring 40 is mounted. The free ends of the protrusions 426 directed radially outward have functional surfaces on their facing 4 longitudinal axis LA of the body 4 of the outlet, which interact with the locking links 38 clutch system 10. The surfaces, respectively, the side surfaces 242 lie at an acute angle to the longitudinal axis LA and thereby form a kind of V-shaped funnel.

The locking links 38 located between the insert 50 of the socket body 4 and the grippers 28, 42 are preferably made in the form of cylindrical bodies, the axes of which lie parallel to the rotary axis D of the handle 6. Their outer diameter corresponds to the inner diameter of the segmented recesses 52 in the outer perimeter of the recess 151 in the insert body 50 while the depth of the segments is less than the radius of the cylindrical bodies. Thus, the cylindrical bodies 38 enter with a geometric closure in the recesses 52, however, their midpoints lie inside the outer perimeter of the recess 151 in the insertion body 50. As shown in Fig. 4, each cylindrical body 38 is loaded with a spring, while the springs 427 lie in the recesses 40 press the cylindrical bodies 38 radially outward into the recesses 52. In this case, the neck portion 423 of the polyhedron grip 42 forms a counter support for the springs 40, which are guided on the sides by the protrusions 426. The locking links 38 can also be balls or other bodies rolling, which includes a form-fitting in corresponding recesses 52 in the insert body 50.

On the opposite side of the projections 425, 426, the main plate 421 of the polyhedron grip 42 carries a cylindrical ledge 428, which extends the tetrahedral recess 424 in the cervical region 423 and is geometrically locked into the passage opening 51 of the insertion body 50. Due to this, the grip 42 has an additional rotary support, which favorably affects the stability of the clutch system 10.

4, the device 1 and thereby the clutch system 10 are shown in the opening position. For example, the handle 6 and thereby the mechanism integrated into the window are in the closing position (6 o'clock position), in which the window is closed and locked. Invisible in FIG. 4, the locking protrusions 34 of the body 4 of the outlet are included with force and geometrical closure in two opposing locking recesses 134 of the handle gripper 28, which lie both in the middle on the longitudinal axis LA of the body 4 of the socket. The locking links 38 of the clutch system 10 enter in the plane below the locking recesses 134 in the grip 28 of the handle with force and geometric closure in two opposite recesses 52 in the insertion body 50, which also lie in the middle on the longitudinal axis LA of the socket body 4. As shown in FIG. 4, two other recesses 52 are formed on both sides of the longitudinal axis LA, for example, at an angular distance of 30 ° each.

The protrusions 285 of the gripper 28 of the handle lie, on the one hand, in the circumferential direction relative to the pivot axis D between the protrusions 425 of the gripper 42 of the polyhedron and, on the other hand, between the other protrusions 426 of the gripper 42 of the polyhedron and the locking elements 38. At the same time, the gripping surfaces 128 of the gripper 26 of the handle and the gripping surfaces 142 of the gripping 42 of the polyhedron are opposite each other with the inclusion of the clearance angle B, while the functional side surfaces 228, 242 of the grippers 28, 42 are facing the locking links 38.

When the handle 6 is rotated from the closing position to the opening position (Fig. 4 to the left), the grip 28 of the grip also rotates to the left until the two diametrically opposite functional side surfaces 228 of the protrusions 285 of the grip 28 of the grip 28 abut laterally into the locking links 38. Since each functional side surface 228 is mounted slightly obliquely with respect to the outer perimeter of the recess 151, and since the (not shown) outer edges of the functional side surfaces 228 are in contact outside the middle with the locking links 3 8, these links are pressed against the action of the spring forces generated by the springs 40 from the recesses 52 in the outer perimeter of the insert 50 so that the cylindrical locking links 38 slide over the edges of the recesses or roll along them. After overcoming the gap In the angle of rotation between the gripping surfaces 128, 142 they enter with force and / or geometrical closure to each other so that the gripper 28 of the handle also rotates the gripper 42 of the polyhedron around the pivot axis D to the left. The tetrahedral rod 8 is carried away by the capture 42 of the polyhedron, due to which the rotary movement of the handle 6 is transmitted to the mechanism integrated in the window. The window can be opened (see figure 5).

If during the pivoting movement the locking links 38 come into other recesses 52 in the insertion body 50, then, as indicated above, they are forced out by the protrusions 285 and their functional side surfaces 228 and pushed further in the circumferential direction. As soon as the handle 6 reaches the opening position, the locking protrusions 34 fall into the locking recesses 134 in the grip 28 of the handle so that the handle 6 is accurately positioned.

If you turn the tetrahedral rod 8, then this movement is transmitted directly to the capture 42 of the polyhedron. Before the gripping surfaces 128 of the gripper 28 of the handle can come into contact with the gripping surfaces 142 of the gripper 42 of the polyhedron and before the functional side surfaces 228 of the protrusions 228 come into contact with the locking links 38, the locking links 38 are pressed in by inclined lying ones before overcoming the clearance B of the turning angle functional side surfaces 242 of the other protrusions 426 of the capture 42 of the polyhedron radially outward into the recesses 52 in the insertion body 50. Thus, the movement of the polyhedron 8 stops GSI by creating between the stop body 4, the locking member 38 and capturing 42 polyhedron geometric and force closure. In this case, each locking link 38 is driven outward by means of the functional surfaces 242 formed on the grip of the polyhedron so that the locking links 38 cannot leave the recesses 52 (see FIG. 6).

Depending on the effect of the force, the cylindrical rollers (locking links) 38 are pressed with remaining deformation into the locking recesses 52 of the insert body 50. Therefore, after an attempt to break in, the device must be replaced with a new device. Thus, using the device according to the invention, hacking attempts can be proved.

Each locking link 38 in each locking position corresponds to two opposite recesses 52 lying opposite each other, so that the clutch system 10 can also withstand heavy loads. Due to the recesses 52 located at equal angular distances from each other in the insertion body 50, it is ensured that the device 1 is protected from unauthorized interference from the outside even when the handle 6 is not exactly in one of its characteristic functional positions, for example, when the handle 6 is not fully reached its position at 6 o’clock.

The processes of fixation occurring during the rotary movement of the handle 6 in the plane of the clutch system are accompanied by the corresponding formation of noise, which is perceived by the user as clicking sounds. This clicking sound signals the presence of a protective mechanism that prohibits the rotation of the handle 6 from the outside through a tetrahedron 8 or a window or door mechanism.

Another advantage of the device according to the invention is that the claws 28, 42 of the clutch system due to their relatively simple geometry can be manufactured with material and cost savings. Installation is also simplified compared to the prior art. The body 4 of the socket, the handle 6 and the grip 28 of the handle, on the one hand, and the grip 42 of the polyhedron, the locking links 38, the corresponding springs 40 and the insertion body 50, on the other hand, can be pre-mounted in the form of structural units, which can then be combined by introducing plug-in body 50 into the body of 4 sockets. This modified installation technology provides the possibility of a modified, material-saving execution of structural elements and thereby contributes to cost reduction.

The invention is not limited to one of the above embodiments, but they can be changed in various ways. However, it can be seen that the invention relates to a device for a window or door containing a thrust body 4, which is intended to be mounted on a window or door, and an actuating device 6 in the form of a handle that is rotatably connected with the thrust body 4. The polyhedron 8 serves to mechanical coupling of the actuating device (handle) 6 with a mechanism integrated in the window or door. The clutch system 10 integrated into the thrust body 4 is used for mechanical coupling and disengagement between the actuating device 6 and the polyhedron 8, while the protective means provided in the clutch system 38, 40, 128, 228 are made and / or arranged so that the devices are actuated 6, the motion is transmitted to the polyhedron 8, so that the polyhedron 8 moves together with the actuator 6, and, conversely, unauthorized acting through the window or door mechanism on the polyhedron 8 voltage once locked, so that the clutch actuating device with the polyhedron remains stationary.

In addition, the invention further provides the possibility of automatically adjusting the length of the protruding beyond the thrust body 4 and inserted into the window or door frame of the polyhedron portion 8a when installing the device 1 on the window or door, while the polyhedron 8 passes through the clutch system 10 inside the actuator 6, while the polyhedron 8 is guided inside the clutch system 10 with the possibility of shear with the course of the HH movement in the direction of its longitudinal axis. In this case, the first stop 8b and at least one more stop 8c define and limit the stroke BH of the movement of the polyhedral rod 8 relative to the clutch system 10, while a spring 18 is located between the polyhedron 8 and the actuator 6, which positions the polyhedron 8 in the axial direction at installing a window or door device on a window or door.

It can be seen that the window or door device 1 for actuating the mechanism integrated into the window or door has a thrust body 4, which is intended to be mounted on a window or door, and a handle 6, which is mounted on the thrust body 4 or axially motionless therein and with the possibility of rotation. The polyhedron 8 serves to mechanically engage the device 1 with a mechanism integrated into the window or door, while the polyhedron 8 acts as a polyhedron portion 8a from the thrust body 4. Using the clutch system 10 formed between the handle 6 and the polyhedron 8, it is possible to transmit torque from the handle 6 to polyhedron 8, but the transmission from the polyhedron 8 to the handle is blocked 6. To enable automatic accounting of various thicknesses of the frame or profile when installed on a window or door, it is provided that o the length L of the polyhedron portion 8a protruding beyond the thrust body 4 and inserted into the window or door frame when the thrust body 4 is mounted on the window or door is automatically adjusted, while the polyhedron 8 is installed in the clutch system 10 with the possibility of sliding in the longitudinal direction, but also without the possibility turning and passes through it into the handle (6).

All the features and advantages arising from the claims, descriptions, or drawings, including structural details, spatial arrangements, and process steps, may be essential to the invention, both on their own and in a wide variety of combinations.

List of items

AT Turn clearance VN Travel progress BR Flanging L Length LA Longitudinal axis D Rotary axis one Device four Stubborn body 5 Blind hole 6 Lever 7 Crank neck 8 Polyhedron 8a Polyhedron site 8b Emphasis 8s Another emphasis 8d the end 9 Neck collar 10 Clutch system 13 Excavation fourteen Cap fifteen Axle 16 Screw eighteen Spring twenty Compression spring 21 Excavation 22 Cervical region 24 Passage hole 26 Screw hole 28 Grip (handles) 34 Fixative 38 Locking link 40 Coil spring 42 Capture (tetrahedron) fifty Plug body 51 Passage hole 52 Retaining recess 55 Locking edge 56 Axle 57 Dismantling recess 58 Groove 71 Excavation 104 Fixing body 114 Jumper 121 Excavation 124 Groove 128 Gripping surface 134 Locking recess 142 Gripping surface 151 Excavation 281 Passage hole 282 Flange section 283 Shaft 284 Step 285 Protrusion 228 Functional surface or side surface 235 Spring jumper 242 Functional surface or side surface 421 Main plate 422 Cutaway 423 Cervical region 424 Recess of the tetrahedron 425 Protrusion 426 Another ledge 427 Nest 428 Ledge

Claims (17)

1. Window or door device (1) for actuating an integrated mechanism in a window or door, comprising a thrust body (4), which is intended to be mounted on a window or door, a handle (6) that is mounted on the thrust body (4) or in it without the possibility of moving in the axial direction, but also with the possibility of rotation, the polyhedron (8) for mechanical engagement of the device (1) with a mechanism integrated into the window or door, the polyhedron (8) being the polyhedron section (8a) behind the thrust body (4 ), and also formed between the handle (6) and a polyhedron (8) a clutch system (10) for transmitting torque from the handle (6) to the polyhedron (8) and blocking its transmission from the polyhedron (8) to the handle (6), characterized in that
the length (L) of the polyhedron extending beyond the thrust body (4) and inserted into the window or door frame (8a) of the polyhedron is automatically adjusted when the thrust body (4) is mounted on the window or door, the polyhedron (8) passing in the clutch system (10) with the ability to move in the longitudinal direction, but without the possibility of rotation, and passes through it into the handle (6), and
the clutch system (10) has two grips (28, 42) provided between the handle (6) and the polyhedron (8), which for a given clearance (B) in the angle of rotation between the gripping surfaces (128, 142) engage with each other with by force and / or geometrical closure so that it is possible to transmit to the polyhedron (8) the movement accompanying the actuation of the handle (6), and the first grip (28) is provided, which is connected without the possibility of rotation with the handle (6), and a second capture (42) which takes many ogrannik (8) non-rotatably, but slidably in the longitudinal direction. 2. The device according to claim 1, characterized in that the polyhedron (8) is installed inside the clutch system (10) with the possibility of shifting by a limited travel (BH) movement along the rotary axis (D) of the handle (6). 3. The device according to claim 2, characterized in that the polyhedron (8) is mounted with the possibility of shear in the longitudinal direction against the force of the spring. 4. The device according to claim 3, characterized in that the polyhedron (8) is supported inside the handle (6) through the compression spring (18). 5. The device according to claim 4, characterized in that the movement of the polyhedron (8) inside the clutch system (10) is limited by at least one stop (8b). 6. The device according to claim 5, characterized in that the polyhedron (8) has at least one other stop (8c), which sets the depth of the polyhedron segment (8a) projecting beyond the stop body (4) into the integrated window or door mechanism. 7. The device according to claim 1, characterized in that the clutch system (10) has at least one locking link (38) provided between the grippers (28, 42) and the stop body (4), which is made and / or located so that it is possible to transfer the torque acting on the handle (6) to the polyhedron (8), however, the torque acting on the polyhedron (8) stops or blocks the movement of the polyhedron, respectively, the actuation of the mechanism integrated into the window or door. 8. The device according to claim 7, characterized in that, to stop the movement of the polyhedron between the stop body (4), each stop link (38) and the second grip (42), it is possible to create a friction, geometric and / or power circuit, and it is possible moving and / or actuating each locking link (38) by means of functional surfaces formed on the grippers (28, 42) or side surfaces (228, 242). 9. The device according to claim 7, characterized in that each locking link (38) is loaded with a spring. 10. The device according to claim 9, characterized in that each locking link (38) is made in the form of a cylindrical body or ball. 11. The device according to claim 7, characterized in that inside the abutment body (4) there are provided locking grooves (52) corresponding to the locking links (38), and at least two locking grooves (52) correspond to each locking link (38) . 12. The device according to claim 11, characterized in that the locking recesses (52) are made in the insertion body (50), which is installed with a force and / or geometric closure in the resistant body (4). 13. The device according to claim 12, characterized in that the plug-in body (50) has a recess (151) in which the grippers (28, 42) are mounted rotatably concentrically to the rotation axis (D) of the handle (6). 14. The device according to claim 1, characterized in that it is possible to fix the first grip (28) using fixing means (34) in at least one characteristic functional position of the handle (6) and / or a mechanism integrated in the window or door . 15. The device according to 14, characterized in that the locking means (34) are formed on the thrust body (4) and upon reaching at least one characteristic functional position, they enter the corresponding locking recesses (134) in the first grip (28 ) 16. The device according to p. 15, characterized in that the fixing means (34) are made as a single unit with a thrust body (4). 17. The device according to clause 16, characterized in that the locking links (38) and locking means (34) are located along the axis (D) of rotation of the handle (6), respectively, of the polyhedron (8) in different planes.

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