RU2120530C1 - Code unit h - Google Patents

Abstract

FIELD: code units. SUBSTANCE: code unit has body with hole accommodating control valve made for communication of pressure source of working medium with user. Body has code disc with indicators. Control valve is made in the form of a package of coaxial turning discs made for engagement with means for their turning. Disc peripheries has holes aligned with disc turning to form main through channel communicating working medium pressure source with user. EFFECT: higher level of coding and operating reliability. 10 cl, 13 dwg

Description

 The invention relates to control systems for locking and protection, in particular to devices for protecting and blocking doors of civil and industrial premises, financial institutions, safes, vehicles, containers, suitcases, cases, as well as technical systems.

 A known lock code mechanism, in the housing of which there is a shaft with a longitudinal groove and a type-setting disk at the end, code rings with recesses and teeth located on the shaft, a locking bar and a roller mounted parallel to the shaft with the possibility of discrete rotation by means of ratchet (USSR Author's Certificate N 1652494, C. E 05 B 37/02, 1991).

 However, the known mechanism is characterized by an insufficiently high level of coding, increased design complexity and low reliability.

 Also known is a lock code assembly comprising a housing with a hole in which a spool is arranged to connect a pressure source of the working fluid to the drive of the locking assembly of the lock (USSR Copyright Certificate N 1227790, class E 05 B 51/02, 1986).

 However, this node also does not have a high level of coding and sufficient reliability due to the use of a fluid that is constantly under pressure as a working fluid, which is why the probability of loss of the working fluid is high.

 The technical result that is expected to be obtained from the use of this invention is to increase the level of coding and operational reliability.

 The specified result is achieved by the fact that in the code node containing the housing with the hole in which the spool is placed, made with the possibility of connecting the pressure source of the working fluid with the consumer, according to the invention, the housing is equipped with a code disk with pointers, and the spool is made in the form of a package of coaxial rotary disks, made with the possibility of interaction with the means of their rotation, moreover, holes are made on the periphery of the disks with the possibility of combining them when the disks rotate and form the main through channel, with connecting the source of pressure of the working fluid with the consumer.

 The package of rotary disks can be equipped with alternating with the last non-rotary disks, on the periphery of which holes are made with the possibility of combining with the holes of the rotary disks during their rotation and the formation of the main through channel.

 In this case, the disk package may be spring loaded.

 The indicated result is also achieved by the fact that each rotary disk can be made of a peripheral part with holes and a central part coaxial with it, interacting with the means of rotation of the rotary disks, and the parts of the disk are provided with means for fixing their mutual rotation.

 In addition, the central parts of the rotary disks can be made with grooves, and the means for rotating the rotary disks can be in the form of a plate, with one end inserted into the grooves of the central part of the corresponding rotary disk, and with the other end pointing to the corresponding pointers of the code disk.

 To facilitate code collection in conditions of insufficient light, the code disk can be divided into sectors with at least two protrusions that limit the angle of rotation of the plate, which is completely inserted by one end into the grooves of the central part of the corresponding rotary disk and in contact with the protrusions by the other end.

 The result is also achieved by the fact that between the code and adjacent non-rotary disks, a ring is fixedly mounted in the hole of the housing and an additional rotary disk is placed coaxially with the latter, in which a slot for the plate and radial holes are made with spring-loaded balls located in them, interacting with profile axial grooves made in the ring.

 On the periphery of at least one rotary and one non-rotary discs, auxiliary holes are made with the possibility of combining them when the rotary disk is rotated and an auxiliary through channel is formed, further connecting the pressure source of the working fluid to the consumer.

 In order to increase the secrecy of the node can be equipped with at least one means of increasing the level of coding, placed at the output of the main through channel and having two drives.

 It is advisable that at the periphery of the at least one rotary and one non-rotary disks, additional holes are made with the possibility of combining them when the rotary disk is rotated and at least one pair of additional through channels is formed, communicating the pressure source of the working fluid with the actuators of the means for increasing the encoding level.

 In FIG. 1 shows the described code node.

 In FIG. 2 is a section AA of FIG. one.

 In FIG. 3 is a section BB of FIG. one.

 In FIG. 4 is a diagram of a code node installation in a lock.

 In FIG. 5 - code unit with composite rotary disks.

 In FIG. 6 is a section BB of FIG. 5.

 In FIG. 7 is a view D of FIG. 5.

 In FIG. 8 - T-shaped plate.

 In FIG. 9 - a cruciform plate.

 In FIG. 10 - code node with an auxiliary end-to-end channel.

 In FIG. 11 - code node with one of the additional end-to-end channels.

 In FIG. 12 is a section DD of FIG. one.

 In FIG. 13 - plate for changing codes.

 The code unit (Fig. 1) contains a housing 1 with a code disk 2 with pointers 3 (Fig. 7) and a cylindrical hole 4, in which a spool is placed, made in the form of a packet of coaxial and alternating rotary disks 5 made with the possibility of interaction with means of their rotation, and non-rotating disks 6. On the periphery of the disks 5, 6 holes 7 are made (Fig. 2, 3) with the possibility of combining them when rotating the rotary disks 5 and the formation of the main through channel 8 (Fig. 4), connecting the working pressure source body made for example , in the form of a pneumatic pump 9 with a working body 10 provided with manual control, in the form of a handle 11, with a consumer, which can be used as a pneumatic actuator 12 with a movable element 13 that interacts with a locking or blocking assembly (not shown) of the lock.

 It is advisable to provide the package of disks 5, 6 with a spring 14. To prevent the possibility of rotation, non-rotating disks 6 are made with diametrically located ledges 15, and the hole 4 is provided with axial grooves 16 for the ledges 15. To ensure a code change, each rotary disk 5 (Fig. 6) can be made of a peripheral part 17 with holes 7 and a central part 18 coaxial with it, which interacts with the means of rotation of the rotary disks 5, and parts 17, 18 of the disk 5 are equipped with fixing means 19 and ledges 20 for fixing their mutual rotation. In this case, the central parts 18 of the rotary disks 5 are made with grooves 21, and the means for turning the rotary disks are in the form of a T-shaped (Fig. 8) or cruciform (Fig. 9) plate 22, with one end 23 inserted into the grooves 21 of the central part 18 of the corresponding rotary disk 5, and the other end 24 pointing to the corresponding pointers 3 of the code disk 2.

 In case of insufficient lighting, the code can be set to the touch. For this, the code disk 2 is divided into four sectors a, b, c, d with the protrusions 25, limiting the angle of rotation of the plate 22, completely inserted with one end 23 into the grooves 21 of the central part 18 of the corresponding rotary disk 5 and in contact with the protrusions 25 with the other end 24 At the same time, the height of the protrusions 25 is less than the immersion depth of the end face 23 in the grooves 21. To simplify the determination of the angle of rotation and the dialing of a code, a ring 26 is fixedly mounted in the cylindrical bore 4 of the housing 1 between the code and adjacent non-rotary disks 2 and 6 and aligned with the last azmeschen additional rotary disc 27 defining a slot 28 for the plate 22 and the radial holes 29 arranged therein spring-loaded balls 30 cooperating with the profile, eg triangular axial grooves 31 made in the ring 26.

 On the periphery of at least one rotary and one non-rotary disks 5, 6, auxiliary holes 32 (Fig. 12) can be made with the possibility of combining them when the rotary disk 5 is rotated and an auxiliary through channel 33 (Fig. 10) is formed, additionally connecting the pump 9 with the drive 12 of the movable element 13 to return to its original position.

 To repeatedly increase the level of coding and protect against unauthorized opening, the node can be equipped with at least one means 34 (Fig. 4) for increasing the level of coding, which is designed to open and close the main through channel 8, placed between it and the consumer, for example, drive 12 of the movable element 13 and has two pneumatic actuators 35, 36. At the same time, additional holes 37, 38 are made on the periphery of at least one rotary and one non-rotary disks 5, 6 with the possibility of combining them with the rotation of the rotary disk 5 and the formation of at least one pair of additional through channels 39, 40 connecting the pump 9 to the actuators 35, 36 of the means 34 for increasing the encoding level.

 The code node operates as follows.

 If you use the code node in the door lock to unlock the latter from the outside, you must dial the correct code on the code disk 2 (Fig. 1, 5, 7). To do this, a plate 22 is inserted into the slot 28 of the disk 27 with the end face 23 (Fig. 8) and rotated until its end 23 is above the grooves 21 (Fig. 3, 6) of the rotary disk 5. The plate 22 will lower and its end 24 touches the end face of the disk 27. Next, the plate 22 is rotated to the mark of the desired code. In this case, the holes 7 are displaced together with the rotary disk 5. Then the plate 22 is removed and another plate 22 (Fig. 9) is inserted with the end 23 into the slot 28 of the disk 27, after which the operation of setting the desired code value is repeated. The encoding level is determined by the number of disks 5, 6. Six disks 5 can provide more than a billion combinations. With a correctly selected code combination, the holes 7 (Fig. 2, 3), made on the periphery of the rotary and non-rotary disks 5, 6, will combine and form the main through channel 8 (Fig. 1) connecting the pump 9 with the cavity 41 of the drive 12. Then it is drawn the handle 11 of the pump 9. The working fluid enters the volume of the pump 9. By a sharp movement of the working body 10 in the opposite direction, the working fluid is pushed along the main through channel 8 into the cavity 41 of the drive 12. The movable element 13 of the drive 12 interacts with the locking lock assembly that opens the door.

 In the case of insufficient illumination of the code disk 2 (Fig. 7) or when there is concern that the code number may be spied, the code may be set to the touch. For this, a plate 22 is inserted into the slot 28 of the disk 27 by the end face 23 and rotates together with the dick 27 until its end 23 is lowered into the grooves 21 of the rotary disks 5. The plate 22 is made with the ends 23, 24 oriented in different configurations, easy to touch the end face 24 of the plate 22 is determined and where the reduced thickness of the side of the end face 23 begins. The end face 23 can enter the grooves 21 of the rotary disk 5 in only one position. By touch, it is easy to determine in which sector of four a, b, c, d the end face 24 of the plate 22 is located. Next, the end face 24 must be transferred to the desired sector a, b, c or d. To do this, turn the plate 22 to the nearest ledge 25 ( Fig. 7) and raise the end face 24 above the protrusion 25. In this case, the end face 23 does not disengage from the grooves 21 of the disk 5. The end face 24 of the plate 22 is lowered in the desired sector a, b, c or d and brought to one of the protrusions 25. After this plate 22 is rotated and the dips of the ball 30 in the grooves 31 (Fig. 1, 5) is counting the desired code. The boundaries of sectors a, b, c, d can be indicated by grooves 31 of an enlarged size. In this case, it is possible to refuse the protrusions 25. After setting the code, the plate 22 is removed and the next plate 22 is lowered (Fig. 9), or the second end of the first plate 22, if the plate 22 is doubled, that is, with two working ends 23. If correct code combination of the hole 7 of the rotary and non-rotary disks 5, 6 (Fig. 2, 3) form a through channel 8 (Fig. 1, 5) connecting the pump 9 to the drive 12.

 In the case of using the means 34 for increasing the coding level (Figs. 4, 11, 12) after setting the desired code on all disks 5, the holes 37 will be combined and form an additional through channel 39, which connects the pump 9 to the first drive 35 of the means 34. The working medium from the pump 9 enters the drive 35 means 34. In this case, the main through channel 8, formed after the main code combination is set, is connected to the drive 12. After the pump 9 is activated, the working fluid enters the cavity 41 of the drive 12, the movable element 13 of which acts on the locking th knot opening the door. To overlap the main through channel 8, a second set of additional holes 38 is used, when combined, a second additional through channel 40 is formed and the working fluid from the pump 9 will go to the second drive 36. In this case, the main channel 8 of the code unit will be disconnected from the drive 12.

 To change the node codes, through the slot 28, a plate 42 is inserted in the disk 27 (Fig. 13), which with its protrusions will enter the grooves 21 of all the rotary disks 5. The cover 43 is removed. Next, the entire package of rotary and non-rotary disks 5, 6 is displaced from the cylindrical hole 4 in the auxiliary cylinder (not shown) with side grooves for the ledges of 15 fixed disks 6. At the end of the auxiliary cylinder a copy of the code disk is applied, repeating the disk 2 of the code unit. To change the code, the fixing means 19 is removed and the peripheral part 17 of the disk 5 is rotated by the desired angle. Next, the tool 19 descends into the ledge 20. The code is replaced and must be recorded. After replacing the codes, the package of rotary and non-rotating disks 5, 6 is inserted into the housing 1, the spring 14 is installed, the cover 43 is screwed and the plate 42 for changing the codes is removed. The code node is ready to go.

Claims (10)

 1. Code assembly comprising a housing with an aperture in which a spool is located, configured to connect a pressure source of the working fluid to a consumer, characterized in that the housing is provided with a code disc with pointers, and the spool is made in the form of a package of coaxial rotary disks made with the possibility of interaction with the means of their rotation, and holes are made on the periphery of the disks with the possibility of combining them when the disks rotate and the formation of the main through channel connecting the working pressure source ate with the consumer.  2. The node according to p. 1, characterized in that the package of rotary disks is equipped with alternating with the last non-rotary disks, on the periphery of which holes are made with the possibility of alignment with the holes of the rotary disks when they are rotated and the formation of the main through channel.  3. The node according to paragraphs. 1 and 2, characterized in that the package of disks is made spring-loaded.  4. The node according to paragraphs. 1 to 3, characterized in that each rotary disk is made of a peripheral part with holes and a central part coaxial to it, interacting with a means of rotation of the rotary disks, and the parts of the disk are equipped with a means for fixing their mutual rotation.  5. The node according to claim 4, characterized in that the central parts of the rotary disks are grooved, and the means for rotating the rotary disks are in the form of a plate, one end inserted into the grooves of the central part of the corresponding rotary disk, and the other end points to the corresponding code disk pointers .  6. The node according to paragraphs. 4 and 5, characterized in that the code disk is divided into sectors by at least two protrusions, limiting the angle of rotation of the plate, completely inserted with one end into the grooves of the Central part of the corresponding rotary disk and in contact with the protrusions by the other end.  7. The node according to paragraphs. 4 - 6, characterized in that between the code and adjacent non-rotary disks, a ring is fixedly mounted in the housing hole and an additional rotary disk is placed coaxially with the latter, in which a slot for the plate and radial holes with spring-loaded balls located in them interacting with the profile axial grooves are made, made in the ring.  8. The node according to paragraphs. 1 to 7, characterized in that on the periphery of at least one rotary and one non-rotary discs, auxiliary holes are made with the possibility of combining them when the rotary disk is rotated and an auxiliary through channel is formed, further connecting the pressure source of the working fluid with the consumer.  9. The node according to paragraphs. 1 to 8, characterized in that it is equipped with at least one means of increasing the level of coding, placed at the output of the main through channel and having two drives.  10. The node according to p. 9, characterized in that on the periphery of the at least one rotary and one non-rotary disks, additional holes are made with the possibility of combining them when the rotary disk is rotated and at least one pair of additional through channels are formed, communicating the pressure source of the working fluid with drives means to increase the level of coding.

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