AT502365B1 - RELEASE AND LOCKING ELEMENT - Google Patents

Description

2 AT 502 365 B1

The invention relates to a release and locking element for locking devices, wherein the blocking element includes a rheological fluid which is variable by a blocking information in its viscosity, and wherein within a sleeve, a piston is movable and in a sealed space between the sleeve and the piston rheological fluid is located.

Previously known locking devices are usually mechanical or electronic devices. Mechanical devices such as all types of door locks, padlocks or the like have been known for a long time. Advantage of these constructions is the simple and cheap production with long known technologies. However, a significant disadvantage is the sometimes insufficient security of such locks against unauthorized locking.

Increased protection against unauthorized access granted electronic locking devices, since in such locks the blocking information is encrypted and can not be imitated with the known technologies. The disadvantage, however, is usually that complicated and complex electronic and mechanical components are necessary to control the blocking elements of such closing technical devices and high energy consumption occurs. Due to the usually complex structure of such electronic locking devices, the designs are expensive to manufacture and often prone to errors due to the many components.

Furthermore, DE 199 246 85 A1 and EP 1 264 992 A1 disclose release and blocking elements for locking devices which can be brought into a release state by means of blocking information, the blocking element including a rheological fluid and its viscosity due to the blocking information is changeable. In the known state of the art are very simple rotary joints or piston couplings with very small effective areas between theological fluid and blocking element.

It is therefore an object of the invention to provide a blocking element for a closing device, which eliminates the above-mentioned disadvantages, compared to the prior art represents an improvement, is simple and inexpensive to manufacture and has a lower maintenance susceptibility and higher blocking safety.

This object is achieved in that the sleeve of the release and locking element is a tube in which the piston is guided and formed between the tube and piston a narrow annular gap for receiving the Theological fluid, and that at the ends of the tube sealing against the piston is arranged, wherein the mutually facing surfaces of the piston and tube, ribs or the like to increase the power transmission.

The theological fluid can be an electrorheological fluid which changes its viscosity when an electric field is applied, or a magnetorheological fluid which changes its viscosity when a magnetic field is applied.

According to a feature of the invention, mechanical and electronic or only electronic means for reading out the blocking information and for applying the electric field or the magnetic field to the rheological fluid are to be provided in the closing devices.

In principle, many of these fluids consist of insulating oils, in which highly polarizable molecules are mixed. These molecules are polarized in the electric or magnetic field, align themselves according to the field and thus solidify the liquid. Due to this solidification, mechanical forces can be transmitted according to the below-mentioned embodiments. 3 AT 502 365 B1

The reaction times of such liquids are in the millisecond range. The control takes place by the application of an electric or magnetic field. In particular, the execution with an electrorheological fluid requires a very low energy, since only a small charge shift is necessary to apply the charges. Thus, there is no need in the cylinder for mechanical parts to be moved by the battery energy when released, which makes the lock construction much simpler and less maintenance-prone.

In closing devices in general it will be advantageous to make the circuit of the release and blocking element so that when the voltage is applied, the release. This would be the more energy efficient option, otherwise voltage would have to be applied over the much longer period of non-release.

A possible embodiment according to the invention of a release and blocking element may be constructed such that a sleeve with pistons movable therein and at least one outlet channel bounded by an elastic membrane and means for applying an electric field or a magnetic field are provided, wherein the rheological fluid within the sleeve is arranged and in the locked state of the release and blocking element by movement of the piston through the outlet channel and through the elastic membrane back into the sleeve is movable, and wherein upon application of an electric field or a magnetic field in the release of the release and Blocking the rheological fluid decreases in their fluidity and thus not or only slightly movable through the outlet channel, whereby the piston is no longer freely movable in the sleeve, but remains in a predefined locking division.

The means for applying an electric field or a magnetic field can be arranged in the vicinity of the outlet channel according to a further feature of the invention and have facing surfaces between which the rheological fluid is located.

In a further embodiment, a piston within a sleeve open on both sides is freely movable, wherein in a sealed space between the sleeve and piston is a rheological fluid which can be increased in the application of an electric field or a magnetic field in its viscosity and thereby the movement the piston can be limited or brought to a standstill in a predefined position. The mutually facing sides between sleeve and piston between which the rheological fluid is in turn can be optimized for power transmission, for example by the formation of ribs or the like in order to form the largest possible effective surface for a non-positive connection can.

By such embodiments of the locking element according to the invention thus not only coupling forces between moving parts can be made, but also forces in the longitudinal direction on pistons, pins or the like can be obtained. In order for these longitudinal forces to be able to release the closing device, the piston can be frictionally connected to corresponding recesses in the closing device.

A possible use of a release and locking element according to the invention is, for example, the use in a door lock cylinder, which on at least one side of the door corresponding actuators and at least one side means for reading the locking information, and slidable in the longitudinal axis of the cylinder and engageable with each other dome pins, and at least one locking lug arranged on the dome bolt, wherein the release and blocking element is arranged in the cylinder between the actuating elements and the dome bolt such that with correct blocking information a force in the longitudinal direction of the actuating element via the release and blocking element is transferable to the dome bolt, and Thus, the door lock cylinder by coupling the two Kuppelboi- zen in the release position can be brought.

As means for reading the blocking information, all common mechanical or electronic read-out devices or combinations thereof can be provided. With correct blocking information, an electrical field or a magnetic field is then applied to the blocking element within the closing device, whereby the viscosity of the theological fluid is increased and there is a frictional connection between the corresponding connection axis and the coupling cylinder of the locking lug.

According to a further feature of the invention may be provided in the closing device means for temperature control, which would block below a certain temperature, which would lead to freezing or too high an increase in viscosity of the Theological fluid, the device, whereby an undesirable Nachsperren can be avoided , For example, all locking components may be equipped with one or more low temperature detection units. For example, a bimetallic strip may be provided in the construction to prevent cold manipulation. Furthermore, all closing technical components can be designed temperature-insulated, which also helps to avoid problems with low temperatures.

Further features of the invention can be found in the claims, the figures and the description.

Fig. 1 shows a schematic longitudinal section through a release and locking element with two mutually facing coupling sides. Fig. 2 shows a longitudinal section through a further embodiment of a release and locking element with mutually facing coupling sides. FIGS. 3-6 show further embodiments of a release and blocking element according to the invention, wherein forces are transmitted in the longitudinal direction. Figures 7 and 8 respectively show schematic sectional views of locking devices in the form of lock cylinders with release and locking element arranged therein. FIG. 9 shows a further embodiment of a door-closing cylinder with a release and blocking element according to the invention arranged therein.

The blocking element shown schematically in Figure 1 has a sleeve of two mutually insulated half-shells 1, 2 with which the respective electrical poles 7, 8 are connected. Within this sleeve are the two coupling sides 30, 31. By means of seals 5, a space is created between these two coupling sides 30, 31 in which the theological fluid, in this case an electrorheological fluid 6, is located. On the actuation axis 3, devices for limiting the speed can be provided, for example in the form of a fly force element, which hooks at high speeds and thus blocks a knob or door handle, for example. In the locked state, no voltage is applied to the half-shells 1, 2 and the theological fluid 6 is in a state of low viscosity. When the actuating shaft 3 is rotated, it rotates freely and there is no further coupling action with the locking lug axis 4. If voltage is applied to the poles 7, 8, then the viscosity of the theological fluid 6 increases, thereby fixed or at least almost solid. If the actuating shaft 3 is rotated, there is a frictional coupling of the coupling side 31 with the locking lug axis 4 on the solidified theological fluid 6. At the locking lug axis 4, it may be necessary to provide a transmission for better power transmission. The electrical voltage can also be applied via the two coupling sides 30, 31. In this case, the sleeve may be continuous and made of an insulating material (not shown).

FIG. 2 shows a further embodiment of an enabling and blocking element. The coupling sides 30 of the actuating shaft 3 are formed in this case in the form of a plurality of rotor discs 10, while the coupling sides 31 of the sperm axis 4 are formed in the form of corresponding recesses in which the rotor discs 10 are freely rotatable. 5 AT 502 365 B1

Between the rotor disks 10 and the corresponding recesses a continuous space is formed, in which the theological fluid 6 is located. This space is further limited by an electrical insulating sleeve 11, which simultaneously acts as a mechanical seal, so that the theological fluid 6 can not escape. Advantage of this Ausges-5 taltung is that the two coupling surfaces 30, 31 are maximized, resulting in an increased non-positive connection via the Theological fluid 6 and thus higher forces can be transmitted.

The schematic longitudinal section shown in FIG. 3 shows a further embodiment of an inventive release and blocking element in which forces can be transmitted in the longitudinal direction. Within a sleeve 9 is a piston 13 which can be moved in the longitudinal direction. In the sleeve, a sealed by seals 5 and an elastic membrane 14, sealed space is formed in which the theological fluid 6 is located. In the embodiment shown in Figure 3, the Theological fluid in the sleeve 15 past two mutually facing active surfaces 32, 33 via an outlet opening 16 in the direction of the elastic membrane 14 to flow when the piston 13 moves into the sleeve and by the residual stress of the elastic membrane 14 back into the sleeve when the piston 13 is moved out of the sleeve 9. If a voltage is applied to the electrical poles 7, 8, the theological fluid solidifies starting from the region 20 between the two action surfaces 32, 33. The flowability of the theological fluid decreases sharply, in particular in this region, as a result of which the piston 13 no longer or only difficult to move back and forth and thus remains in a predefined position, whereby a locking process can be triggered. This locking process can subsequently be carried out by the non-positive or positive engagement of the piston 13 in corresponding Ausnehmun-25 conditions in the closing device.

Figures 4 and 5 show alternative embodiments of a release and blocking element, which works according to the principle of Figure 3. In the embodiment shown in FIG. 4, the active surface 33, to which the electric pole 8 is connected, is fastened via an insulating disk 15 to one side of the sleeve 9. The outlet openings 16 are located along the circumference of the sleeve 9 and the isolated space is bounded by an elastic membrane ring or by a plurality of appropriately arranged elastic membranes on the outer circumference of the sleeve 9.

FIG. 5 shows an embodiment in which the active surfaces 32, 33 constrict in the direction of the outlet opening 16. Here, too, the rheological fluid 6 solidifies upon application of a voltage to the poles 7, 8 whereby the fluidity decreases, especially in this area and towards the outlet opening 16 and the piston 13 remains in a predefined position with corresponding blocking information. FIG. 6 shows a schematic sectional view of a further possible embodiment of an enabling and blocking element according to the invention. In this case, a two-sided piston 17 is movably arranged in a two-sided open sleeve 19, by seals 5 and insulating rings 18, a space between the sleeve and piston is created, in which the theological fluid 6 is located. In the locked state, the piston can move freely back and forth within the sleeve 45. Upon application of a voltage to the electric poles 7, 8, the theological fluid 6 solidifies, whereby it comes between the piston 17 and the sleeve 19 to a frictional connection, which greatly limits the longitudinal movement or completely prevented. In order to reinforce this non-positive connection between the sleeve 19 and the piston 17, the corresponding facing sides, so the inner circumference of the sleeve 19 and the outer periphery of the piston 17 may be configured such that they are optimized for power transmission. This can be achieved, for example, by the formation of ribs 34. As already shown in the exemplary embodiments of FIGS. 3 to 5, the piston 17 of the embodiment shown in FIG. 6 can cooperate with corresponding recesses within the device for releasing the closing device. 55 6 AT 502 365 B1

Figure 7 shows a schematic representation of a closing device, in this case a door lock cylinder with a release and blocking element. The locking lug 23 is connected via a locking lug axis 4, the insulating ring 18 and the insulating sleeve 11 with a rotor 22. The rotor 22 is located within an insulating sleeve 11, which together with the correspondingly formed actuating axis 3 form a sealed space in which the rheological fluid is located. On the actuation axis 3 is further the knob 21, which is used to open the door, and on the other hand, for example, may include the means for reading the lock information. The entire structure is housed in a housing 20. When a voltage is applied to the poles 7, 8, the viscosity of the theological fluid surrounding the rotor 22 increases, whereby a frictional connection between the actuating shaft 3 and the locking lug axis 4 is formed.

FIG. 8 shows a schematic view of another closing device. In this embodiment, a two-sided door-closing cylinder, the knobs 21 via respective actuation axes 3, insulating washers 15, insulating pieces 26, connecting axes 25, 28 and the coupling sleeve 29 connected to each other throughout. The axes are arranged in a common sleeve through the entire lock cylinder in the housing 20 and are held by retaining rings 24 in position. About this sleeve, a clutch cylinder 27 is arranged, which is connected to the locking lug 23. Between the clutch cylinder 27 and the coupling sleeve 29 is a sealed by seals 5 space in which the rheological fluid 6 is located. When a voltage is applied to the coupling sleeve 29 with respect to the coupling cylinder 27, the solidified rheological fluid causes a frictional connection between the clutch cylinder 27 and the locking lug 23 and the continuous sleeve on which the actuating axes 3 and the knobs 21 are located.

Fig. 9 shows a door lock cylinder with release and locking element arranged therein according to one of the embodiments of FIGS. 3 to 5, in the example shown, an element according to FIG. 3. The actuation of the lock cylinder is effected by pressing and turning the knob 21 and the thereto If no correct blocking information was previously transmitted, the force of the depression of the knob 21 is transmitted to the piston 13 via the actuating axis 3 and the force limiting spring 35. In this case, since no electric field has been applied across the poles 7, 8, the rheological fluid 6 is free to flow and fills the space bounded by the elastic membrane 14. This results in no further power transmission to the coupling pin 38 and thus to no connection with the coupling pin 39. The return spring 41 ensures when releasing the knob for the return of the release and locking element in the normal position.

Now, if a correct blocking information is transmitted, an electric field is built up, whereby the rheological fluid 6 hardens. If a force is exerted in the longitudinal direction on the knob 21 and the actuating shaft 3, so this is transferred to the piston 13. After the rheological fluid 6 is now hardened, they can no longer flow freely into the space bounded by the elastic membrane 14 and it comes to a power transmission to the sleeve 9 of the release and locking element. Subsequently, this force is transmitted in the longitudinal direction of the coupling pin 38, which is thereby displaced inwardly and engages in the coupling pin 39. If a rotational movement is subsequently carried out on the knob 21, it is transmitted via the driving sleeve 40 to the coupling pin 39 and via the gear 37 to the locking nose axis 4 and thus to the locking nose 23. Upon release of the knob, the return springs 36 effect both the decoupling of the coupling pins 38, 39 and the provision of the piston 13 of the release and locking element.

Further elements, such as various readout devices for blocking information, power-limiting or amplifying transmissions and devices, speed-limiting devices and lock mechanisms, as known in the prior art, can be described in corresponding

Claims (9)

7 AT 502 365 B1 the way combined with the release and blocking element according to the invention and are therefore not described in detail. 1. Release and blocking element for closing technical devices, wherein the blocking element includes a rheological fluid which is variable by a blocking information in its viscosity, and wherein within a sleeve, a piston is movable and in a sealed space between the sleeve and the piston is located rheological fluid, characterized in that the sleeve (9, 19) is a tube in which the piston (13, 17) is guided and between the tube (9, 19) and piston (13, 17) has a narrow annular gap for receiving the theological fluid (6) is formed, and that at the ends of the tube (9, 19) a seal (5) with respect to the piston (13, 17) is arranged, wherein the mutually facing surfaces of piston and tube, ribs (34 ) or the like to increase the power transmission. 2. Release and blocking element according to claim 1, characterized in that the rheological fluid (6) is an electrorheological fluid which changes its viscosity when an electric field is applied, or a magnetorheological fluid which changes its viscosity when a magnetic field is applied. 3. Release and blocking element according to claim 1 or 2, characterized in that mechanical and electronic or only electronic means for reading out the blocking information and for applying the electric field or the magnetic field to the rheological fluid (6) are provided in the closing devices , 4. release and blocking element according to one of claims 1 to 3, characterized in that a sleeve (9) with therein movable piston (13), and at least one by an elastic membrane (14) limited outlet channel (16) and means for applying an electric field (7, 8) or a magnetic field are provided, wherein the rheological fluid (6) within the sleeve (9) is arranged and in the locked state of the release and locking element by movement of the piston through the outlet channel (16) out and through the elastic membrane (14) back into the sleeve (9) is movable, and wherein upon application of an electric field or a magnetic field upon release of the release and blocking element, the rheological fluid (6) decreases in its fluidity and thus not or only slightly through the outlet channel (16) is movable, whereby the piston (13) is no longer freely in the sleeve (9) movable but in a predefined Sperrste ilung remains. 5. Release and blocking element according to claim 4, characterized in that the means for applying an electric field (7, 8) or a magnetic field in the vicinity of the outlet channel (16) are arranged and have mutually facing surfaces (32, 33), between which the rheological fluid (6) is located. 6. release and blocking element according to one of claims 1 to 3, characterized in that within a sleeve open to both sides (19) of the piston (17) is freely movable, being in a sealed space between the sleeve (19) and piston (17) is a rheological fluid (6) which can be increased in the installation of an electric field or a magnetic field in their viscosity and whereby the movement of the piston (17) can be limited or brought to a standstill in a defined position. 7. Release and blocking element according to one of claims 4 to 6, characterized in that the piston (13, 17) or the sleeve (9, 19) with a corresponding recess in the closing device is positively connected, whereby the device in 8 AT 502 365 B1 release position can be brought. 8. release and blocking element according to one of claims 1 to 7, characterized in that the closing device is a door closing cylinder, which on at least one side of the door corresponding actuating elements (21) and at least one side means for reading the blocking information, and in Längsachsrichtung of the cylinder displaceable and engageable with each other dome pin (38, 39), and at least one on the coupling pin (39) arranged locking lug (23), wherein the release and locking element in the cylinder between the actuating elements (21) and the coupling pin (36 ) Is arranged such that when correct blocking information, a force in the longitudinal direction of the actuating element (21) via the release and blocking element on the coupling pin (38) is transferable, and thus the door lock cylinder by coupling the two coupling pins (38, 39) in the release position brought is. 9. release and blocking element according to one of claims 1 to 8, characterized in that the closing device by means for temperature control falls below a certain temperature, which would lead to freezing or too high an increase in viscosity of the Theological fluid (6), blockable is, so that an unwanted unlocking is avoidable. For this purpose 5 sheets of drawings