CN104153651A - Full-automatic lock cylinder structure on basis of driving rope - Google Patents

Abstract

The invention relates to a full-automatic lock cylinder structure on the basis of a driving rope. The full-automatic lock cylinder structure used for a lock hole of a mating part comprises a part body, and is characterized by further comprising a motor, a receiving antenna, a control board, a lock cylinder matched with the lock hole, the driving rope and guide devices. The motor and the receiving antenna are respectively connected with the control board electrically, one end of the lock cylinder is arranged on the driving rope, and the driving rope is wound around the guide devices to be connected with the motor. When an external control device transmits part locking commands, the receiving antenna transmits the commands to the motor, the motor drives the driving rope to move anticlockwise under guide of the guide devices, the driving rope drives the lock cylinder to move, so that the lock cylinder is pushed into the lock hole, and the part body and the mating part can be automatically locked; when the external control device transmits part unlocking commands, the motor drives the driving rope to move clockwise, actions reverse to the part locking commands are executed and the part body and the mating part are automatically unlocked.

Description

Full-automatic lock core structure based on driving rope

Technical Field

The invention relates to the field of lock cylinders, in particular to a full-automatic lock cylinder structure based on a transmission rope.

Background

In daily life, two matching parts are often required to be fastened so as to achieve the purpose of fixing the parts, such as a box cover and a box body which are common in daily life. In order to achieve the fixation between the components, the common fastening methods of the components are mainly classified into the following methods: one is to fasten the two parts by using the fastening principle, namely, a structure which can be fastened with a matched part is arranged on one part; the second is to adopt a thread structure, namely, thread structures which can be screwed mutually are respectively arranged on two matching parts, and the two matching parts are fixed through a rotating part; the other type is a fastening structure design with a lock cylinder, namely, the lock cylinder is arranged on one component, the lock hole is arranged on the other matched component, and the lock cylinder is pushed into the lock hole in a manual mode, so that the locking and fastening work between the two components is completed, for example, the fastening of a box cover and a box body and the fastening between two doors with door pins are typical examples of the application of the lock cylinder structure.

However, the conventional component fastening structure design still has some disadvantages: on one hand, the locking and unlocking work between the component and the matched component needs manual intervention, which wastes manpower and reduces the working efficiency; on the other hand, in an environment requiring remote control, such as a nuclear radiation environment, locking and unlocking actions among remote control parts are often required, and the existing lock cylinder structure cannot meet the requirement.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a full-automatic lock cylinder structure based on a transmission rope, which can automatically realize the locking and unlocking work between a component and a matched component, aiming at the prior art.

The technical scheme adopted by the invention for solving the problems is as follows: the utility model provides a full-automatic lock core structure based on driving rope for to the lockhole on the supporting parts, including the part body, its characterized in that still includes motor, receiving antenna, control panel, with lockhole complex lock core, driving rope and guider, motor, receiving antenna carry out the electricity with the control panel respectively and are connected, the one end setting of lock core is on the driving rope, the driving rope is walked around guider and is connected with the motor.

Optionally, the receiving antenna is disposed on a periphery of the component body.

Optionally, the number of said guides is at least two.

Preferably, the guide means is a fixed pulley.

Optionally, the lock cylinders are respectively arranged on four peripheries of the component body, and the number of the lock cylinders is at least four.

Optionally, the lock cylinder is a direct-connect lock cylinder.

Optionally, the lock cylinder is a connecting rod type lock cylinder, the connecting rod type lock cylinder is arranged on the periphery of the component body, the connecting rod type lock cylinder comprises a first movable rod and a second movable rod, the first movable rod is matched with the lock hole, one end of the second movable rod is movably connected with the first movable rod, and the other end of the second movable rod is arranged on the transmission rope.

Further, optionally, full-automatic lock core structure based on driving rope still includes the guide rail groove and can be at the ejector pin of guide rail groove removal, and the one end and the second movable rod of connecting rod formula lock core of ejector pin are connected, and the other end and the driving rope of ejector pin are connected, and the guide rail groove sets up on the part body, and the guide rail groove with driving rope parallel arrangement.

Compared with the prior art, the invention has the advantages that: when the external control equipment sends a locking component command, the receiving antenna sends the command to the motor, then the motor drives the transmission rope to move anticlockwise under the guiding action of the guiding device, and the movement of the transmission rope drives the movement of the lock cylinder, so that the lock cylinder is pushed into the lock hole, and the automatic locking between the component and the matched component is realized; when the external control equipment sends a component opening command, the motor drives the transmission rope to move clockwise, and then the action opposite to the component locking command is executed, so that the automatic opening between the component and the matched component is realized.

Drawings

FIG. 1 is a schematic structural diagram of a fully automatic lock cylinder structure based on a driving rope according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a full-automatic lock cylinder structure based on a driving rope according to a second embodiment of the present invention;

fig. 3 is a schematic structural view of a full-automatic lock cylinder structure based on a driving rope in the third embodiment of the invention.

Detailed Description

The invention is described in further detail below with reference to the accompanying examples.

In this embodiment, a fully automatic lock cylinder structure provided on a box cover is described, and the kit is the box cover and the box body. As shown in fig. 1, 2 and 3, the full-automatic lock cylinder structure based on the transmission rope of the invention is used for aiming at a lock hole 1 on a box body 2, and comprises a box cover body 3, and as an improvement, the full-automatic lock cylinder structure further comprises a motor 4, a receiving antenna 5, a control board 6, a lock cylinder matched with the lock hole 1 and a guiding device 8, wherein the motor 4 and the receiving antenna 5 are respectively electrically connected with the control board 6, one end of the lock cylinder is arranged on the transmission rope 9, and the transmission rope 9 bypasses the guiding device 8 and is connected with the motor 4. The lock cylinder is divided into a direct-connection type lock cylinder 71 and a link type lock cylinder including a first movable bar 721 and a second movable bar 722. Wherein,

the motor 4 can rotate clockwise or anticlockwise so as to drive the transmission rope 9 to move clockwise or anticlockwise on the box cover body 3;

the receiving antenna 5 is used for receiving signal commands sent by external control equipment, such as a handheld RFID transmitter, and transmitting the signal commands to the control board 6;

and the control board 6 is used for receiving the signal command transmitted by the receiving antenna 5 and controlling the rotating speed and the rotating direction of the motor 4. The size of one end of the lock cylinder, which enters the lock hole 1, is smaller than or equal to the size of the lock hole 1, so that the lock cylinder and the lock hole 1 are firmly fixed.

Further, in order to reduce the attenuation of the external control signal and effectively improve the strength and receiving effect of the signal received by the receiving antenna 5, the receiving antenna 5 is optionally disposed on the periphery of the box cover body 3.

In order to push the lock cylinder on the box cover body 3 into the lock hole 1 of the box body 2 and realize the comprehensive and firm locking between the box cover and the box body, the lock cylinder is selectively arranged on the periphery of the box cover body 3.

Further, in order to ensure that the box cover and the box body are tightly locked and can realize the balance of the box cover and the box body in the moving process, the lock cylinders are selectively arranged on the four peripheries of the box cover body 3 respectively, and the number of the lock cylinders is at least four. When the lock cylinders arranged on the four peripheries of the box cover body 3 are pushed into the lock holes 1 of the box body 2, firm locking is realized between the box cover and the box body, and the box cover is not easy to open.

When the transmission rope 9 drives the lock cylinder to move, the guide device 8 is optionally a fixed pulley in order to not only keep the trend of the transmission rope 9, but also reduce the resistance borne by the transmission rope 9 in the motion process. Further, the number of the fixed pulleys is four, and the fixed pulleys are respectively arranged on four peripheries of the box cover body 3.

The first embodiment is as follows:

as shown in fig. 1, the lock cylinder of the full-automatic lock cylinder structure in the first embodiment adopts a direct-connected lock cylinder 71, one end of the direct-connected lock cylinder 71 is arranged on the transmission rope 9, and the other end of the direct-connected lock cylinder 71 is located at a position corresponding to the lock hole 1, so that the direct-connected lock cylinder 71 can be smoothly pushed into the lock hole 1 of the box body 2.

The following describes the operation of the fully automatic lock cylinder structure in the first embodiment with reference to fig. 1:

(1) an external control device, such as a handheld RFID transmitter, sends a box cover locking command to a receiving antenna 5 on the box cover;

(2) the receiving antenna 5 receives a box cover locking command sent by external control equipment and sends the box cover locking command to the control panel 6;

(3) the control panel 6 receives a box cover locking command and controls the starting and rotating speed of the motor 4 to rotate in the forward direction;

(4) the motor 4 rotates in the positive direction, the lead screw drives the transmission rope 9 to move anticlockwise, and the moving direction of the transmission rope 9 is controlled by the guiding action of the fixed pulley;

(5) the transmission rope 9 moves to drive the direct-connected lock cylinder 71 to move along the direction of the transmission rope 9, and then one end, matched with the lock hole 1, of the direct-connected lock cylinder 71 is pushed into the lock hole 1 of the box body 2, so that the box cover and the box body are locked;

(6) and (3) when the external control equipment sends a box cover opening command, sequentially executing the operations opposite to the operations in the steps (2) to (5), and finally completing the opening action between the box cover and the box body in the locking state.

Example two:

as shown in fig. 2, the lock cylinder of the full-automatic lock cylinder structure in the second embodiment adopts a link-type lock cylinder matched with the lock hole, the link-type lock cylinder is disposed on the periphery of the box cover body 3, the link-type lock cylinder includes a first movable rod 721 matched with the lock hole 1 and a second movable rod 722, the first movable rod 721 is movably connected with one end of the second movable rod 722, and the other end of the second movable rod 722 is disposed on the driving rope 9.

When the driving rope 9 moves counterclockwise by the rotation of the motor 4 and drives the second movable rod 722 to move along the moving direction of the driving rope 9, the second movable rod 722 applies a pushing force to the first movable rod 721 toward the lock hole 1. However, due to the flexibility of the driving cord 9, the direction of the pushing force applied to the first movable rod 721 by the second movable rod 722 is deviated, so that the first movable rod 721 cannot smoothly and accurately enter the locking hole 1 of the cabinet 2. Therefore, in order to ensure that the second movable rod 722 applies a thrust force with a correct direction to the first movable rod 721, so that the first movable rod 721 can smoothly and accurately enter the lock hole 1, optionally, the full-automatic lock cylinder structure further includes a guide rail groove 10 and a top bar 11 capable of moving on the guide rail groove 10, one end of the top bar 11 is connected with the second movable rod 722 of the link lock cylinder, the other end of the top bar 11 is connected with the driving rope 9, the guide rail groove 10 is disposed on the box cover body 3, and the guide rail groove 10 is parallel to the driving rope 9. Wherein, the guide rail groove 10 plays a role in correcting the motion direction of the mandril 11. Thus, when the driving rope 9 moves counterclockwise, the push rod 11 in the guide rail groove 10 moves in the moving direction of the driving rope 9, the push rod 11 applies a pushing force to the second movable rod 722 in the direction of the lock hole 1, and the second movable rod 722 applies a pushing force to the first movable rod 721 in the direction of the lock hole 1, thereby pushing the first movable rod 721 into the lock hole 1 of the case 2.

The following describes the operation process of the full-automatic lock cylinder structure in the second embodiment with reference to fig. 2:

(1) an external control device, such as a handheld RFID transmitter, sends a box cover locking command to a receiving antenna 5 on the box cover;

(2) the receiving antenna 5 receives a box cover locking command sent by external control equipment and sends the box cover locking command to the control panel 6;

(3) the control panel 6 receives a control command for locking the box cover, controls the starting and rotating speed of the motor 4 and carries out forward rotation;

(4) the motor 4 rotates in the positive direction, the lead screw drives the transmission rope 9 to move anticlockwise, and the moving direction of the transmission rope 9 is controlled by the guiding action of the fixed pulley;

(5) the transmission rope 9 moves to drive the ejector rod 11 in the guide rail groove 10 to move along the movement direction of the transmission rope 9, then the ejector rod 11 applies a pushing force to the second movable rod 722 of the connecting rod type lock cylinder in the direction of the lock hole, and then the second movable rod 722 is slowly perpendicular to the horizontal direction of the ejector rod 11;

(6) in the process that the second movable rod 722 is slowly perpendicular to the horizontal direction of the top rod 11, the second movable rod 722 always applies thrust to the first movable rod 721;

(7) the first movable rod 721 is slowly pushed into the lock hole 1 of the box body 2 under the action of the pushing force of the second movable rod 722, so that the locking action of the box cover and the box body is completed;

(8) and (3) when the external control equipment sends a control command for opening the box cover, sequentially executing the operations opposite to the operations in the steps (2) to (7), and finally completing the opening action between the box cover and the box body in the locking state.

Example three:

as shown in fig. 3, the lock cylinder of the full automatic lock cylinder structure in the third embodiment adopts both the direct-connected lock cylinder 71 in the first embodiment and the link-type lock cylinder in the second embodiment. The number of the direct-connected lock cylinders 71 and the number of the link-type lock cylinders can be set according to specific conditions. In the third embodiment, the number of the direct-connected lock cylinders 71 and the number of the link-type lock cylinders are respectively set to four, and one direct-connected lock cylinder 71 and one link-type lock cylinder are respectively arranged on each periphery of the box cover body 2.

The working process of the full-automatic lock cylinder structure in the third embodiment refers to the first embodiment and the second embodiment, wherein the action of the direct-connected lock cylinder 71 is synchronous with the action of the link-type lock cylinder.

Claims (8)

1. The utility model provides a full-automatic lock core structure based on driving rope for to the lockhole on the supporting parts, including the part body, its characterized in that still includes motor, receiving antenna, control panel, with lockhole complex lock core, driving rope and guider, motor, receiving antenna carry out the electricity with the control panel respectively and are connected, the one end setting of lock core is on the driving rope, the driving rope is walked around guider and is connected with the motor.

2. The actuator cord-based fully automatic cylinder structure of claim 1, wherein the receiving antenna is disposed on the periphery of the component body.

3. The automatic transmission cord-based lock cylinder structure according to claim 2, wherein the number of the guide means is at least two.

4. The driveline-based fully automatic cylinder structure of claim 3, wherein the guiding means is a fixed pulley.

5. The driving cord-based fully automatic cylinder structure according to any one of claims 1 to 4, wherein the cylinders are respectively provided on four peripheries of the component body, and the number of cylinders is at least four.

6. The driving-cord-based fully automatic cylinder lock structure according to any one of claims 1 to 4, wherein the cylinder lock is a direct-connect cylinder lock and/or a link cylinder lock.

7. The full-automatic lock cylinder structure based on the driving rope according to any one of claims 1 to 4, wherein the lock cylinder is a link-type lock cylinder, the link-type lock cylinder is disposed on the periphery of the component body, the link-type lock cylinder includes a first movable rod and a second movable rod, the first movable rod is engaged with the lock hole, the first movable rod is movably connected with one end of the second movable rod, and the other end of the second movable rod is disposed on the driving rope.

8. The full-automatic lock cylinder structure based on the driving rope according to claim 7, further comprising a guide rail groove and a top bar capable of moving on the guide rail groove, wherein one end of the top bar is connected with the second movable rod of the connecting rod type lock cylinder, the other end of the top bar is connected with the driving rope, the guide rail groove is arranged on the component body, and the guide rail groove is arranged in parallel with the driving rope.