CN205743319U - Electronic lock control mechanism - Google Patents

Abstract

A kind of electronic lock control mechanism, it is characterised in that: lock housing, its side is run through dead bolt hole, and another side is run through sleeve hole；In dead bolt is located at the dead bolt hole of lock housing and there is dead bolt breach；Sleeve is located in the sleeve hole of lock housing, and rear end is provided with flange, and flange outer sides is provided with at least one flange recess, and sleeve is axially equipped with lock core hole；Core, has lockhole, and in being located at the lock core hole of sleeve and end has eccentric convex cylindrical, bias convex cylindrical is installed in dead bolt breach；Additionally, lock housing has a chute, accommodating trip and elastic parts, one end of elastic parts is resisted against trip rear end, and the other end is resisted against chute inwall, and trip front end is for withstanding the flange recess of sleeve；And actuator, it is located in lock housing, blocks trip for band pendulum lock pin, make sleeve arbitrarily to rotate.

Description

Electronic lock control mechanism

Technical field

This utility model is related to a kind of electronic lock control mechanism, a kind of electronic lock mechanisms with induction lock and key lock two kinds lock.

Background technology

Progress and social transition along with science and technology; modern improves day by day for the attention of gate inhibition's safety, and in order to be effectively improved the safety in residence at home, general door is substantially all and is mounted with door lock; protection based on door lock so that home safety and lives and properties are obtained guarantee.

The most common general electronic type door lock, during use, input pre-set password or can enter with sensor sensing electronic type door lock, the necessity of carrying keys can be omitted, increase the convenience on using, but, general man memory is limited, easily forget unlocking pin or leave behind sensor under hasty, and when the electricity of the battery set by electronic type door lock inside exhausts, electronic type door lock also cannot be unlocked, in order to release the locking condition of electronic type door lock, electronic type door lock is destroyed by unique mode exactly, inconvenience is still had on using, really remain to be further improved.

Because existing electronic type door lock forgets Password user or leaves behind the battery electric quantity of sensor or electronic type door lock with when exhausting, electronic type door lock all cannot be unlocked, the electronic lock control mechanism that the utility model proposes is provided with traditional locks core structure and electronic type locked instrument in lock housing simultaneously, no matter electronic lock all with electronic type or corresponding key can be unlocked or lock by user, increases the convenience on using.

Utility model content

In order to solve the problem that above-mentioned conditional electronic lock uses, main purpose of the present utility model is providing a kind of electronic lock control mechanism, and including lock housing, lock housing includes the first side and the second side, and the first side is run through dead bolt hole, and the second side is run through sleeve hole；Dead bolt is located in dead bolt hole movably linearly, and dead bolt has dead bolt breach；Sleeve is located in sleeve hole, and sleeve rear end is provided with flange, and flange outer sides is provided with at least one flange recess, and sleeve is axially equipped with lock core hole；Core has lockhole, is located in lock core hole and end has eccentric convex cylindrical, and bias convex cylindrical is installed in dead bolt breach, in order to drive dead bolt to move；Chute is located in lock housing, and in order to accommodating trip and elastic parts such as spring, elastic parts one end is resisted against the first rear end of trip, and the other end is resisted against chute inwall, and trip front end is in order to withstand the flange recess of sleeve, in order to limit the rotation of sleeve；In microswitch is located at lock housing and it is connected with circuit module, presses microswitch, the proving program of microswitch start-up circuit module in trip；And actuator is located in lock housing, blocking trip in order to band pendulum lock pin, make trip cannot withstand the flange recess of sleeve, sleeve can arbitrarily rotate；Wherein, trip front end has at least one angular rim, in order to make the flange recess of sleeve be pushed in chute by trip along the angular rim of trip, makes the first rear end of trip push down elastic parts, and the second rear end of trip presses microswitch.

On the one hand, the electronic lock control mechanism of offer of the present utility model, including: lock housing includes the first side and the second side, and the first side is run through dead bolt hole, and the second side is run through sleeve hole；Dead bolt is located in dead bolt hole movably linearly, and dead bolt has dead bolt breach；Sleeve is located in sleeve hole, and this sleeve rear end is provided with flange, and flange outer sides is provided with at least one flange recess, and sleeve is axially equipped with lock core hole；Core has lockhole, is located in lock core hole and end has eccentric convex cylindrical, and bias convex cylindrical is installed in dead bolt breach, in order to drive dead bolt to move；First chute and the second chute, it is located in lock housing, and first chute and the second chute homonymy arrange, first chute houses trip and the first elastic parts such as spring, first elastic parts one end is resisted against the rear end of trip, the other end is resisted against the first chute inwall, and trip front end is in order to withstand the flange recess of sleeve, in order to limit the rotation of sleeve；Second chute houses moving part and the second elastic parts such as spring, and second elastic parts one end is resisted against the first rear end of moving part, and the other end is resisted against the second chute inwall, and moving part front end is resisted against the eccentric convex cylindrical of core；In microswitch is located at lock housing and it is connected with circuit module, presses microswitch, the proving program of microswitch start-up circuit module in moving part；And actuator is located in lock housing, blocking trip in order to band pendulum lock pin, make trip cannot withstand the flange recess of sleeve, sleeve can arbitrarily rotate；Wherein, trip front end has at least one angular rim, in order to make the flange recess of sleeve be pushed in the first chute by trip along the angular rim of trip；Wherein, the eccentric convex cylindrical of core promotes moving part, makes the first rear end of moving part push down the second elastic parts, and the second rear end of moving part presses microswitch.

On the other hand, the electronic lock control mechanism of offer of the present utility model, including: lock housing includes the first side and the second side, and the first side is run through dead bolt hole, and the second side is run through sleeve hole；Dead bolt is located in dead bolt hole movably linearly, and dead bolt has dead bolt breach；Sleeve is located in sleeve hole, and sleeve rear end is provided with flange, and flange outer sides is provided with at least one flange recess, and sleeve is axially equipped with lock core hole；Core has lockhole, and core is located in lock core hole and end has eccentric convex cylindrical, and bias convex cylindrical is installed in dead bolt breach, in order to drive dead bolt to move；First chute and the second chute, it is located in lock housing, and first chute and the second chute be oppositely arranged, first chute houses the first trip and the first elastic parts, first elastic parts one end is resisted against the first rear end of this first trip, the other end is resisted against the first chute inwall, first trip front end is in order to withstand the flange recess of sleeve, in order to limit the rotation of sleeve, second chute houses the second trip and the second elastic parts, second elastic parts one end is resisted against the first rear end of the second trip, and the other end is resisted against the second chute inwall；In microswitch is located at lock housing and it is connected with circuit module, presses this microswitch, the proving program of microswitch start-up circuit module in the second trip；And；Actuator is located in lock housing, blocks the first trip in order to band pendulum lock pin, makes the first trip withstand the flange recess of sleeve, and sleeve cannot arbitrarily rotate；Wherein, the first trip has two angular rim, in order to make the flange recess of sleeve be pushed in the first chute by the first trip along the first trip angular rim；Wherein, second trip has two angular rim, in order to make the flange recess of sleeve be pushed in the second chute by the second trip along the second trip angular rim, making the first rear end of the second trip push down the second elastic parts, the second rear end of the second trip presses microswitch.

It yet still another aspect, the electronic lock control mechanism of offer of the present utility model, including: lock housing outdoors, runs through in lock housing outdoors and is provided with sleeve hole；Sleeve is located in sleeve hole, and barrel forward end is knob outdoors, and sleeve middle-end is provided with flange, and flange outer sides is provided with at least one flange recess, and sleeve is axially equipped with lock core hole；Core is located in lock core hole and has lockhole；First chute and one second chute, it is located in lock housing, and first chute and the second chute be oppositely arranged, first chute houses the first trip and the first elastic parts, first elastic parts one end is resisted against the first rear end of the first trip, the other end is resisted against the first chute inwall, first trip front end is in order to withstand the flange recess of sleeve, in order to limit the rotation of sleeve, second chute houses the second trip and the second elastic parts, second elastic parts one end is resisted against the first rear end of the second trip, and the other end is resisted against the second chute inwall；Microswitch is located at and in lock housing and is connected with circuit module outdoors, presses microswitch, the proving program of microswitch start-up circuit module in the second trip；And；Actuator, is located at outdoors in lock housing, blocks the first trip in order to band pendulum lock pin, make the first trip withstand the flange recess of sleeve, and sleeve cannot arbitrarily rotate；Lock hook lock housing is set in parallel in outdoors after lock housing, includes the first side, the second side and the 3rd side, and the first side is run through lock hook hole, and perforation runs through the second side and the 3rd side；Lock hook part is rotatably disposed within lock hook lock housing and has snap fit extended retraction lock hook hole, and lock hook part has guide groove；Follower lever chute is located in lock hook lock housing, in order to accommodating follower lever and the 5th elastic parts such as spring, follower lever has cylinder, cylinder is located in the guide groove of lock hook part, in order to drive lock hook part to rotate, the snap fit making lock hook part stretches out this lock hook hole of retraction, and the 5th elastic parts one end is resisted against the rear end of follower lever, and the other end is resisted against follower lever chute inwall；Eccentric is socketed in outside hollow axle tube, both synchronous rotaries, and hollow axle tube front end is located in the perforation of the 3rd side of lock hook lock housing, and hollow axle tube rear end is located in the perforation of the second side of lock hook lock housing, and wherein, the front end of follower lever is resisted against in the outer rim of eccentric；After door inner lock shell is set in parallel in lock hook lock housing, door inner lock shell includes the first side and the second side, and the first side is provided with perforation in door, and the second side is provided with cage knob hole；Dominant control has axially penetrated through through hole, dominant control front end has protuberance, in order to affixed with hollow axle tube rear end, dominant control rear end indent forms accommodation space, in order to accommodating interlock plate, first pawl and the second pawl, first pawl and the second pawl are rotatably disposed within dominant control, interlock plate has the first pawl groove and the second pawl groove, the first pawl groove can be withstood in first pawl front end, the second pawl groove can be withstood in second pawl front end, interlock plate is made to rotate, there is in accommodation space the 3rd chute and the 4th chute, 3rd chute houses the 3rd elastic parts such as spring, 4th chute houses the 4th elastic parts such as spring, 3rd elastic parts one end is resisted against the first pawl side, the other end is resisted against the 3rd chute inwall, 4th elastic parts one end is resisted against the second pawl side, the other end is resisted against the 4th chute inwall；Cage knob is placed in the cage knob hole of an inner lock shell, affixed with dominant control, cage knob and dominant control synchronous rotary；Transmission shaft lever, front end is affixed with core rear end through the perforation of hollow axle tube and the 3rd side of lock hook lock housing, and transmission shaft lever rear end is affixed with interlock plate through the perforation of the second side of lock hook lock housing and the through hole of dominant control；Wherein, the first trip has an angular rim, in order to make the flange recess of sleeve be pushed in the first chute by the first trip along the first trip angular rim；Wherein, the second trip has an angular rim, in order to make the flange recess of sleeve be pushed in the second chute by the second trip along the second trip angular rim, makes the first rear end of the second trip push down elastic parts, and the second rear end of the second trip presses microswitch；Wherein, there is on the protuberance of dominant control at least one arcuation groove, hollow axle tube rear end has the arcuation projection that at least one is corresponding with the arcuation groove of dominant control, and arcuation projection protrudes the perforation of the second side of lock hook lock housing and corresponding the combining closely of arcuation groove of dominant control；Wherein, dominant control rear end has at least one projection, there is outside cage knob at least one groove corresponding with the projection of dominant control, combine closely corresponding with the groove of cage knob of the projection of dominant control；Wherein, interlock plate central authorities are equipped with power transmission shaft rod aperture, and transmission shaft lever may pass through power transmission shaft rod aperture and drives interlock plate synchronous rotary；Wherein, core rear end has a groove corresponding with transmission shaft lever front end geometry, in order to make core combine closely with transmission shaft lever front end.

Through the electronic lock control mechanism that the utility model proposes, can reach that there are on electronic lock electronic lock and two kinds of locked mechanisms of key lock simultaneously, select easily in order to user to use key or electronic type to unblank.

Accompanying drawing explanation

Fig. 1 is this utility model first embodiment electronic lock control mechanism front perspective exploded view；

Fig. 2 is this utility model first embodiment electronic lock control mechanism back side schematic perspective view；

Fig. 3 is this utility model first embodiment electronic lock control mechanism schematic rear view when locking；

Fig. 4 is the schematic rear view during unblock of this utility model first embodiment electronic lock control mechanism；

Fig. 5 is the schematic rear view after this utility model first embodiment electronic lock control mechanism unlocks；

Fig. 6 is this utility model the second embodiment electronic lock control mechanism front perspective exploded view；

Fig. 7 is this utility model the second embodiment electronic lock control mechanism back side schematic perspective view；

Fig. 8 is this utility model the second embodiment electronic lock control mechanism schematic rear view when locking；

Fig. 9 is the thin portion enlarged diagram that this utility model the second embodiment electronic lock control mechanism removes moving part when locking；

Figure 10 is the schematic rear view during unblock of this utility model the second embodiment electronic lock control mechanism；

Figure 11 is the thin portion enlarged diagram removing moving part during the unblock of this utility model the second embodiment electronic lock control mechanism；

Figure 12 is the schematic rear view after this utility model the second embodiment electronic lock control mechanism unlocks；

Figure 13 is the thin portion enlarged diagram removing moving part after this utility model the second embodiment electronic lock control mechanism unlocks；

Figure 14 is this utility model the 3rd embodiment electronic lock control mechanism front perspective exploded view；

Figure 15 is this utility model the 3rd embodiment electronic lock control mechanism back side schematic perspective view；

Figure 16 is this utility model the 3rd embodiment electronic lock control mechanism schematic rear view when locking；

Figure 17 is the schematic rear view during unblock of this utility model the 3rd embodiment electronic lock control mechanism；

Figure 18 is the schematic rear view after this utility model the 3rd embodiment electronic lock control mechanism unlocks；

Figure 19 is this utility model the 4th embodiment electronic lock control mechanism perspective exploded view；

Figure 20 is this utility model the 4th embodiment electronic lock control mechanism lock housing front perspective exploded view outdoors；

Figure 21 a is this utility model the 4th embodiment electronic lock control mechanism lock housing back side schematic perspective view outdoors；

Figure 21 b is this creation the 4th embodiment electronic lock control mechanism lock housing back side perspective exploded view outdoors；

Figure 22 is this utility model the 4th embodiment electronic lock control mechanism lock hook lock housing back side perspective exploded view；

Figure 23 is this utility model the 4th embodiment electronic lock control mechanism lock hook lock housing back side schematic perspective view；

Figure 24 is this utility model the 4th embodiment electronic lock control mechanism door inner lock shell front perspective exploded view；

Figure 25 is this utility model the 4th embodiment electronic lock control mechanism interlock plate back side schematic perspective view；

Figure 26 is this utility model the 4th embodiment electronic lock control mechanism dominant control back side schematic perspective view；

Figure 27 is this utility model the 4th embodiment electronic lock control mechanism dominant control and cage knob perspective exploded view；

Figure 28 is this utility model the 4th embodiment electronic lock control mechanism generalized section；

Figure 29 is this utility model the 4th embodiment electronic lock control mechanism schematic rear view of lock housing outdoors when locking；

Figure 30 is this utility model the 4th embodiment electronic lock control mechanism schematic rear view of lock hook lock housing when locking；

Figure 31 is the schematic rear view of lock hook lock housing after this utility model the 4th embodiment electronic lock control mechanism unlocks；And

Figure 32 is this utility model the 4th embodiment electronic lock control mechanism schematic rear view of lock housing outdoors when unlocking.

Detailed description of the invention

This utility model is to disclose a kind of electronic lock control mechanism, and the general utility functions sex knowledge of the most each relevant parts should be correlative technology field tool usually intellectual and can understand, therefore following narration, no longer another is completely description.Graphic with hereinafter institute's reference, is to express with this utility model about the schematic diagram of feature, and not according to actual size is completely drawn, conjunction is first chatted bright.

First, refer to Fig. 1, for this utility model first embodiment electronic lock control mechanism front perspective exploded view.As shown in Figure 1, in first embodiment of the present utility model, electronic lock 1 controlling organization includes lock housing 11, dead bolt 12, sleeve 13, core 14 and key 15, and the first side 1101 of lock housing 11 is run through and is provided with dead bolt hole 1103, and the second side 1102 of lock housing 11 is run through and is provided with sleeve hole 1104；Dead bolt 12 is located in the dead bolt hole 1103 of lock housing 11 movably linearly, and dead bolt 12 has dead bolt breach 121；Sleeve 13 is located in the sleeve hole 1104 of lock housing 11, and sleeve 13 rear end is provided with flange 131, is provided with two flange recess 1311 outside flange 131, and sleeve 13 axially penetrates through and is provided with lock core hole 132；Core 14 has lockhole 141, core 14 is located in the lock core hole 132 of sleeve 13, and core 14 end has eccentric convex cylindrical 142, and eccentric convex cylindrical 142 is installed in dead bolt breach 121, when core 14 rotates, the eccentric convex cylindrical 142 of core 14 end can drive dead bolt 12 to move；If lockhole 141 is not inserted into key 15, core 14 is integrated with sleeve 13, can synchronous rotary.

Then, Fig. 2 is referred to, for this utility model first embodiment electronic lock control mechanism back side schematic perspective view.As shown in Figure 2, there is in lock housing 11 chute 16 and can house trip 17 and spring 18, one end of spring 18 is resisted against the first rear end 171 of trip 17, the other end is resisted against chute 16 inwall, trip 17 is promoted by the elastic force of spring 18 and withstands the flange recess 1311 of the flange 131 of sleeve 13 with the front end of trip 17, limits the rotation of sleeve 13；nullIn microswitch 19 is located at lock housing 11 and it is connected with circuit module 110，When the second rear end 172 of trip 17 presses microswitch 19，The microswitch 19 i.e. proving program of start-up circuit module 110 is verified，After being proved to be successful，Actuator 111 i.e. band pendulum lock pin 112 blocks trip 17，Make trip 17 cannot withstand the flange recess 1311 of flange 131 of sleeve 13，Sleeve 13 can arbitrarily rotate，Wherein，Trip 17 front end has an angular rim 173，In order to make the flange recess 1311 of the flange 131 of sleeve 13 be pushed in chute 16 by trip 17 along the angular rim 173 of trip 17，Make the first rear end 171 pressing spring 18 of trip 17，Second rear end 172 of trip 17 presses microswitch 19，Therefore the angular rim 173 of trip 17 so can make sleeve 13 can one direction rotate，Sleeve 13 one direction is unrestricted.

Then, referring to Fig. 3 to Fig. 5, Fig. 3 is this utility model first embodiment electronic lock control mechanism schematic rear view when locking；Fig. 4 is the schematic rear view during unblock of this utility model first embodiment electronic lock control mechanism；Fig. 5 is the schematic rear view after this utility model first embodiment electronic lock control mechanism unlocks.As shown in Figure 3, when this utility model first embodiment electronic lock control mechanism is locked, the flange recess 1311 of the flange 131 of sleeve 13 is withstood in the front end of trip 17, limit sleeve 13 to rotate, and the angular rim 173 of trip 17 makes sleeve 13 can rotate toward counterclockwise 100, now, sleeve 13 and core 14 synchronous rotary, when core 14 rotates counterclockwise, the eccentric convex cylindrical 142 of end rolls in the dead bolt breach 121 of dead bolt 12, until the eccentric convex cylindrical 142 of core 14 end is limited by dead bolt breach 121 and cannot roll.

This utility model first embodiment electronic lock control mechanism, key 15 can be used to unlock or lock, during unblock, key 15 is inserted lockhole 141, make past 200 half rotation clockwise of core 14, as it is shown on figure 3, the eccentric convex cylindrical 142 through core 14 end rolls at the dead bolt breach 121 of dead bolt 12, and then drive dead bolt 12 to move down, reach to unlock purpose；Otherwise, when locking, key 15 drives core 14 counterclockwise 200 half rotation, makes dead bolt 12 move up, reaches purpose of locking.

nullWhen this utility model first embodiment electronic lock control mechanism is locked，It is used as remote controller to unlock，During unblock，First sleeve 13 is rotated toward counterclockwise 100，Trip 17 is pushed in chute 16 by the flange recess 1311 making the flange 131 of sleeve 13 along the angular rim 173 of trip 17，Now，Trip 17 pushes down microswitch 19，As shown in Figure 4，The proving program of microswitch 19 start-up circuit module 110 is verified，After being proved to be successful，Actuator 111 i.e. rotarily drives lock pin 112 and upwards blocks trip 17，Make trip 17 cannot limit sleeve 13 again to rotate，Then sleeve 13 is rotated toward clockwise 200，Because trip 17 is kept off by lock pin 112，The flange recess 1311 of the flange 131 of sleeve 13 cannot be withstood，Sleeve 13 can be smoothly toward 200 half rotation clockwise，Core 14 and sleeve 13 synchronous rotary simultaneously，The eccentric convex cylindrical 142 of core 14 end rolls in the dead bolt breach 121 of dead bolt 12，And then drive dead bolt 12 to move down，Reach to unlock purpose，Wherein，During unblock，During sleeve 13 rotates toward clockwise 200，Circuit module 110 controls actuator 111 and rotates，Band pendulum lock pin 112 is downward，Make trip 17 unrestricted，When sleeve 13 rotates to next flange recess 1311，Trip 17 is promoted by the elastic force of spring 18，Release microswitch 19，Trip 17 withstands the flange recess 1311 of the flange 131 of sleeve 13，Sleeve 13 is made to rotate toward clockwise 200 again，As shown in Figure 5；After unblock, as being intended to lock, directly sleeve 13 can be rotated toward counterclockwise 100, drive dead bolt 12 up to move, reach purpose of locking；During unblock, sleeve 13 is rotated toward counterclockwise 100, makes trip 17 press microswitch 19 start-up circuit module 110 and verify, after being proved to be successful, actuator 111 rotarily drives lock pin 112, after fixing number of seconds, actuator 111 is auto-reverse, makes lock pin 112 downwards, no longer blocks trip 17；When locking, being rotated toward counterclockwise 100 by sleeve 13, make trip 17 push down microswitch 19, now, circuit module 110 has set actuator 111 and will not rotate, therefore will not band pendulum lock pin 112 move.

Refer to Fig. 6, for this utility model the second embodiment electronic lock control mechanism front perspective exploded view.As shown in Figure 6, in the second embodiment of the present utility model, electronic lock 2 controlling organization includes lock housing 21, dead bolt 22, sleeve 23, core 24 and key 25, and the first side 2101 of lock housing 21 is run through and is provided with dead bolt hole 2103, and the second side 2102 of lock housing 21 is run through and is provided with sleeve hole 2104；Dead bolt 22 is located in the dead bolt hole 2103 of lock housing 21 movably linearly, and dead bolt 22 has dead bolt breach 221；Sleeve 23 is located in the sleeve hole 2104 of lock housing 21, and sleeve 23 rear end is provided with flange 231, is provided with two flange recess 2311 outside flange 231, and sleeve 23 axially penetrates through and is provided with lock core hole 232；Core 24 has lockhole 241, core 24 is located in the lock core hole 232 of sleeve 23, and core 24 end has eccentric convex cylindrical 242, and eccentric convex cylindrical 242 is installed in dead bolt breach 221, when core 24 rotates, the eccentric convex cylindrical 242 of core 24 end can drive dead bolt 22 to move；If lockhole 241 is not inserted into key 25, core 24 is integrated with sleeve 23, can synchronous rotary.

Then, Fig. 7 is referred to, for this utility model the second embodiment electronic lock control mechanism back side schematic perspective view.As shown in Figure 7, there is in lock housing 21 first chute 26 and the second chute 29 arranged with the first chute 26 homonymy, first chute 26 houses trip 27 and the first spring 28, one end of first spring 28 is resisted against the rear end of trip 27, the other end is resisted against the first chute 26 inwall, trip 27 is promoted by the elastic force of the first spring 28 and withstands the flange recess 2311 of the flange 231 of sleeve 23 with the front end of trip 27, limits the rotation of sleeve 23；Second chute 29 houses moving part 210 and the second spring 211, second spring 211 one end is resisted against the first rear end 21001 of moving part 210, the other end is resisted against the second chute 29 inwall, and moving part 210 is promoted by the elastic force of the second spring 29 and is resisted against the eccentric convex cylindrical 242 of core 24 with front end；nullIn microswitch 212 is located at lock housing 21 and it is connected with circuit module 213，When core 24 rotates，The eccentric convex cylindrical 242 of core 24 i.e. can promote moving part 210，The second spring 211 is pushed down in the first rear end 21001 making moving part 210，Second rear end 21002 of moving part 210 presses microswitch 212，The microswitch 212 i.e. proving program of start-up circuit module 213 is verified，After being proved to be successful，Actuator 214 i.e. band pendulum lock pin 215 blocks trip 27，Make trip 27 cannot withstand the flange recess 2311 of flange 231 of sleeve 23，Sleeve 23 can arbitrarily rotate，Wherein，Trip 27 front end has an angular rim 271，In order to make the flange recess 2311 of the flange 231 of sleeve 23 be pushed in the first chute 26 by trip 27 along the angular rim 271 of trip 27，Therefore the angular rim 271 of trip 27 so can make sleeve 23 can one direction rotate，Sleeve 23 one direction is unrestricted.

Then, referring to Fig. 8 to Figure 12, Fig. 8 is this utility model the second embodiment electronic lock control mechanism schematic rear view when locking；Fig. 9 is the thin portion enlarged diagram that this utility model the second embodiment electronic lock control mechanism removes moving part when locking；Figure 10 is the schematic rear view during unblock of this utility model the second embodiment electronic lock control mechanism；Figure 11 is the thin portion enlarged diagram removing moving part during the unblock of this utility model the second embodiment electronic lock control mechanism；Figure 12 is the schematic rear view after this utility model the second embodiment electronic lock control mechanism unlocks；Figure 13 is the thin portion enlarged diagram removing moving part after this utility model the second embodiment electronic lock control mechanism unlocks.As can be seen from figures 8 and 9, when this utility model the second embodiment electronic lock control mechanism is locked, the flange recess 2311 of the flange 231 of sleeve 23 is withstood in the front end of trip 27, limits sleeve 23 and rotates, and the angular rim 271 of trip 27 makes sleeve 23 can rotate toward counterclockwise 300.

This utility model the second embodiment electronic lock control mechanism, key 25 can be used to unlock or lock, during unblock, key 25 is inserted lockhole 241, making core 24 toward 400 half rotation clockwise, as shown in Figure 8, the eccentric convex cylindrical 242 through core 24 end rolls in the dead bolt breach 221 of dead bolt 22, and then drive dead bolt 22 to move down, reach to unlock purpose；Otherwise, when locking, key 25 drives core 24 counterclockwise 300 half rotation, makes dead bolt 22 move up, reaches purpose of locking, wherein, when unlocking with key 25 and lock, moving part 210 all will not be made to press microswitch 212.

nullWhen this utility model the second embodiment electronic lock control mechanism is locked，It is used as remote controller to unlock，During unblock，First sleeve 23 is rotated toward counterclockwise 300，Trip 27 is pushed in the first chute 26 by the flange recess 2311 making the flange 231 of sleeve 23 along the angular rim 271 of trip 27，Now，Core 24 and sleeve 23 synchronous rotary，The eccentric convex cylindrical 242 of core 24 i.e. can promote moving part 210，The second spring 211 is pushed down in the first rear end 21001 making moving part 210，Second rear end 21002 of moving part 210 presses microswitch 212，As shown in Figure 10，The proving program of microswitch 212 start-up circuit module 213 is verified，After being proved to be successful，Actuator 214 i.e. rotarily drives lock pin 215 and upwards blocks trip 27，As shown in figure 11，Make trip 27 cannot limit sleeve 23 again to rotate，Then sleeve 23 is rotated toward clockwise 400，Because trip 27 is kept off by lock pin 215，The flange recess 2311 of the flange 231 of sleeve 23 cannot be withstood，Sleeve 23 can be smoothly toward 400 half rotation clockwise，Core 24 and sleeve 23 synchronous rotary simultaneously，The eccentric convex cylindrical 242 of core 24 end rolls in the dead bolt breach 221 of dead bolt 22，And then drive dead bolt 22 to move down，Reach to unlock purpose，Wherein，During unblock，During sleeve 23 rotates toward clockwise 400，Circuit module 213 controls actuator 214 and rotates，Band pendulum lock pin 215 is downward，Make trip 27 unrestricted，The eccentric convex cylindrical 242 of core 24 rotates simultaneously，Moving part 210 is made not suppressed，Moving part 210 is promoted by the elastic force of the second spring 211，Release microswitch 212，When sleeve 23 rotates to next flange recess 2311，Trip 27 is promoted by the elastic force of the first spring 28，Withstand the flange recess 2311 of sleeve 23，Sleeve 23 is made to rotate toward clockwise 400 again，As shown in FIG. 12 and 13；After unblock, as being intended to lock, directly sleeve 23 can be rotated toward counterclockwise 300, drive dead bolt 22 up to move, reach purpose of locking；During unblock, sleeve 23 is rotated toward counterclockwise 300, makes trip 27 push down microswitch 212 start-up circuit module 213 and verify, after being proved to be successful, actuator 214 rotarily drives lock pin 215, after fixing number of seconds, actuator 111 is auto-reverse, makes lock pin 215 downwards, no longer blocks trip 27；When locking, sleeve 23 is rotated toward counterclockwise 300, now, moving part 210 will not press microswitch 212, when only unlocking, moving part 210 just can press microswitch 212 and then start proving program, second embodiment electronic lock 2 controlling organization of the present utility model transmits through mechanism's start and clearly instructs, and saves circuit module 213 and judges the time of electronic lock 2 state, and any unusual condition can be avoided to occur and cause remote controller to unlock unsuccessfully.

Refer to Figure 14, for this utility model the 3rd embodiment electronic lock control mechanism front perspective exploded view.As shown in figure 14, in the 3rd embodiment of the present utility model, electronic lock 3 controlling organization includes lock housing 31, dead bolt 32, sleeve 33, core 34 and key 35, and the first side 3101 of lock housing 31 is run through and is provided with dead bolt hole 3103, and the second side 3102 of lock housing 31 is run through and is provided with sleeve hole 3104；Dead bolt 32 is located in the dead bolt hole 3103 of lock housing 31 movably linearly, and dead bolt 32 has dead bolt breach 321；Sleeve 33 is located in the sleeve hole 3104 of lock housing 31, and sleeve 33 rear end is provided with flange 331, is provided with two flange recess 3311 outside flange 331, and sleeve 33 axially penetrates through and is provided with lock core hole 332；Core 34 has lockhole 341, core 34 is located in the lock core hole 332 of sleeve 33, and core 34 end has eccentric convex cylindrical 342, and eccentric convex cylindrical 342 is installed in dead bolt breach 321, when core 34 rotates, the eccentric convex cylindrical 342 of core 34 end can drive dead bolt 32 to move；If lockhole 341 is not inserted into key 35, core 34 is integrated with sleeve 33, can synchronous rotary.

Then, Figure 15 is referred to, for this utility model the 3rd embodiment electronic lock control mechanism back side schematic perspective view.As shown in figure 15, there is in lock housing 31 first chute 36 and the second chute 39 being oppositely arranged with the first chute 36, first chute 36 houses the first trip 37 and the first spring 38, one end of first spring 38 is resisted against the first rear end 371 of the first trip 37, the other end is resisted against the first chute 36 inwall, first trip 37 is promoted by the elastic force of the first spring 38 and withstands the flange recess 3311 of the flange 331 of sleeve 33 with the front end of the first trip 37, limits the rotation of sleeve 33；Second chute 39 houses the second trip 310 and the second spring 311, second spring 311 one end is resisted against the first rear end 31001 of the second trip 310, the other end is resisted against the second chute 39 inwall, second trip 310 is promoted by the elastic force of the second spring 311 and withstands the flange recess 3311 of the flange 331 of sleeve 33 with the front end of the second trip 310, limits the rotation of sleeve 33；nullIn microswitch 312 is located at lock housing 31 and it is connected with circuit module 313，When the second spring 311 is pushed down in the first rear end 31001 of the second trip 310，Second rear end 31002 of the second trip 310 presses microswitch 312，The microswitch 312 i.e. proving program of start-up circuit module 313 is verified，After being proved to be successful，Actuator 314 i.e. band pendulum lock pin 315 is downward，No longer block the first trip 37，Make the first trip 37 cannot withstand the flange recess 3311 of flange 331 of sleeve 33，Sleeve 33 can arbitrarily rotate，Wherein，First trip 37 front end has two angular rim 373，In order to make the flange recess 3311 of the flange 331 of sleeve 33 be pushed in the first chute 36 by first trip 37 along the angular rim 373 of the first trip 37，Second trip 310 front end has two angular rim 31003，In order to make the flange recess 3311 of the flange 331 of sleeve 33 be pushed in the second chute 39 by second trip 310 along the angular rim 31003 of the second trip 310，The second spring 311 is pushed down in the first rear end 31001 making the second trip 310，Second rear end 31002 of the second trip 310 presses microswitch 312，The angular rim 373 of the first trip 37 and the angular rim 31003 of the second trip 310 make the sleeve 33 can bidirectional rotary，But because the first trip 37 is limited by lock pin 315，Therefore，First trip 37 cannot be pushed by sleeve 33 toward the first chute 36，But the size of flange recess 3311 of the flange 331 because of sleeve 33，Make the rotatable certain angle of sleeve 33 (such as Figure 16)，Therefore sleeve 33 can bidirectional rotary certain angle.

Then, referring to Figure 16 to Figure 18, Figure 16 is this utility model the 3rd embodiment electronic lock control mechanism schematic rear view when locking；Figure 17 is the schematic rear view during unblock of this utility model the 3rd embodiment electronic lock control mechanism；Figure 18 is the schematic rear view after this utility model the 3rd embodiment electronic lock control mechanism unlocks.As shown in figure 16, when this utility model the 3rd embodiment electronic lock control mechanism is locked, the flange recess 3311 of the flange 331 of sleeve 33 is withstood in the front end of the first trip 37, limit sleeve 33 to rotate, and the size of the flange recess 3311 of the flange 331 of sleeve 33 makes the sleeve 33 can bidirectional rotary certain angle.

This utility model the 3rd embodiment electronic lock control mechanism, key 35 can be used to unlock or lock, during unblock, key 35 is inserted lockhole 341, making core 34 toward 600 half rotation clockwise, as shown in figure 16, the eccentric convex cylindrical 342 through core 34 end rolls at the dead bolt breach 321 of dead bolt 32, and then drive dead bolt 32 to move down, reach to unlock purpose；Otherwise, when locking, key 35 drives core 34 counterclockwise 500 half rotation, makes dead bolt 32 move up, reaches purpose of locking.

nullWhen this utility model the 3rd embodiment electronic lock control mechanism is locked，It is used as remote controller to unlock，During unblock，First sleeve 33 is rotated toward clockwise 600，Second trip 310 is pushed in the second chute 39 by the flange recess 3311 making the flange 331 of sleeve 33 along the angular rim 31003 of the second trip 310，Now，The second spring 311 is pushed down in first rear end 31001 of the second trip 310，Second rear end 31002 of the second trip 310 presses microswitch 312，As shown in figure 17，The proving program of microswitch 312 start-up circuit module 313 is verified，After being proved to be successful，It is downward that actuator 314 i.e. rotarily drives lock pin 315，No longer block the first trip 37，Make the first trip 37 cannot limit sleeve 33 again to rotate，Then sleeve 33 is rotated toward clockwise 600，Because the first trip 37 is not kept off by lock pin 315，The flange recess 3311 of the flange 331 of sleeve 33 cannot be withstood，Sleeve 33 can be smoothly toward 600 half rotation clockwise，Core 34 and sleeve 33 synchronous rotary simultaneously，The eccentric convex cylindrical 342 of core 34 end rolls at the dead bolt breach 321 of dead bolt 32，And then drive dead bolt 32 to move down，Reach to unlock purpose；nullAfter unblock，As being intended to lock，Sleeve 33 need to be rotated toward counterclockwise 500，Second trip 310 is pushed in the second chute 39 by the flange recess 3311 making the flange 331 of sleeve 33 along the angular rim 31003 of the second trip 310，Now，The second spring 311 is pushed down in first rear end 31001 of the second trip 310，Second rear end 31002 of the second trip 310 presses microswitch 312，As shown in figure 17，The proving program of microswitch 312 start-up circuit module 313 is verified，After being proved to be successful，It is downward that actuator 314 i.e. rotarily drives lock pin 315，No longer block the first trip 37，Make the first trip 37 cannot limit sleeve 33 again to rotate，Then sleeve 33 is rotated toward counterclockwise 500，Because the first trip 37 is not kept off by lock pin 315，The flange recess 3311 of the flange 331 of sleeve 33 cannot be withstood，Sleeve 33 can be smoothly toward counterclockwise 500 half rotation，Core 34 and sleeve 33 synchronous rotary simultaneously，The eccentric convex cylindrical 342 of core 34 end rolls at the dead bolt breach 321 of dead bolt 32，And then drive dead bolt 32 to move up，Reach purpose of locking；During unblock, sleeve 33 is rotated toward clockwise 600, making the second trip 310 press microswitch 312 start-up circuit module 313 to verify, after being proved to be successful, actuator 314 rotarily drives lock pin 315, after fixing number of seconds, actuator 314 is auto-reverse, makes lock pin 315 upwards, blocks the first trip 37, first trip 37 withstands the flange recess 3311 of the flange 331 of sleeve 33, makes sleeve 33 to rotate to an angle；In like manner, when locking, sleeve 33 is rotated toward counterclockwise 500, makes the second trip 310 press microswitch 312 start-up circuit module 313 and verify, after being proved to be successful, actuator 314 rotarily drives lock pin 315, and after fixing number of seconds, actuator 314 is auto-reverse, make lock pin 315 upwards, blocking the first trip 37, the first trip 37 withstands the flange recess 3311 of the flange 331 of sleeve 33, makes sleeve 33 to rotate to an angle.When 3rd embodiment electronic lock 3 controlling organization of the present utility model uses remote controller unlock or lock, sleeve 33 only needs one direction two-period form to rotate, such as: during unblock, dextrorotation rotaring sleeve 33 2 times, when locking, turnbarrel 33 2 times counterclockwise, is not required to as first, second embodiment needs bidirectional rotary unlock or lock, and operation seems relatively intuition.

Refer to Figure 19, for this utility model the 4th embodiment electronic lock control mechanism perspective exploded view.As shown in figure 19, in the 4th embodiment of the present utility model, electronic lock 4 controlling organization forms combined by lock housing 41 outdoors, lock hook lock housing 42 and door inner lock shell 43, and lock hook lock housing 42 is set in parallel in outdoors after lock housing 41, after door inner lock shell 43 is set in parallel in lock hook lock housing 42.

Then Figure 20 is referred to, for this utility model the 4th embodiment electronic lock control mechanism lock housing front perspective exploded view outdoors.As shown in figure 20, in the 4th embodiment of the present utility model, run through in lock housing 41 outdoors and be provided with sleeve hole 4101, sleeve 411 is located in the sleeve hole 4101 of lock housing 41 outdoors, sleeve 411 front end is knob 41101 outdoors, sleeve 411 middle-end is provided with flange 41102, is provided with two flange recess 411021 outside flange 41102, and sleeve 411 is axially equipped with lock core hole 41103；Core 413 has lockhole 41301, and core 413 is located in the lock core hole 41103 of sleeve 411, if lockhole 41301 is not inserted into key 414, core 413 is integrated with sleeve 411, can synchronous rotary.

Then, referring to Figure 21 a and Figure 21 b, Figure 21 a is this utility model the 4th embodiment electronic lock control mechanism lock housing back side schematic perspective view outdoors；Figure 21 b is this utility model the 4th embodiment electronic lock control mechanism lock housing back side perspective exploded view outdoors.As shown in fig. 21b, in the 4th embodiment of the present utility model, core 413 rear end has the groove 41302 corresponding with transmission shaft lever 412 front end geometry, makes core 413 combine closely with transmission shaft lever 412 front end；There is in lock housing 41 first chute 415 and the second chute 418 being oppositely arranged with the first chute 415 outdoors, first chute 415 houses the first trip 416 and the first spring 417, one end of first spring 417 is resisted against the first rear end 4161 of the first trip 416, the other end is resisted against the first chute 415 inwall, first trip 416 is promoted by the elastic force of the first spring 417 and withstands the flange recess 411021 of the flange 41102 of sleeve 411 with the front end of the first trip 416, limits the rotation of sleeve 411；Second chute 418 houses the second trip 419 and the second spring 4110, second spring 4110 one end is resisted against the first rear end 4191 of the second trip 419, the other end is resisted against the second chute 418 inwall, second trip 419 is promoted by the elastic force of the second spring 4110 and withstands the flange recess 411021 of the flange 41102 of sleeve 411 with the front end of the second trip 419, limits the rotation of sleeve 411；nullMicroswitch 4111 is located at and in lock housing 41 and is connected with circuit module 4112 outdoors，When the second spring 4110 is pushed down in the first rear end 4191 of the second trip 419，Second rear end 4192 of the second trip 419 presses microswitch 4111，The microswitch 4111 i.e. proving program of start-up circuit module 4112 is verified，After being proved to be successful，Actuator 4113 i.e. band pendulum lock pin 4114 is upwards，No longer block the first trip 416，Make the first trip 416 cannot withstand the flange recess 411021 of flange 41102 of sleeve 411，Sleeve 411 can arbitrarily rotate，Wherein，First trip 416 front end has an angular rim 4163，In order to make the flange recess 411021 of the flange 41102 of sleeve 411 be pushed in the first chute 415 by first trip 416 along the angular rim 4163 of the first trip 416，Second trip 419 front end has an angular rim 4193，In order to make the flange recess 411021 of the flange 41102 of sleeve 411 be pushed in the second chute 418 by second trip 419 along the angular rim 4193 of the second trip 419，The second spring 4110 is pushed down in the first rear end 4191 making the second trip 419，Second rear end 4192 of the second trip 419 presses microswitch 4111，Therefore the angular rim 4193 of the angular rim 4163 of the first trip 416 and the second trip 419 makes sleeve 411 one direction to rotate，But because the first trip 416 is limited by lock pin 4114，Therefore，First trip 416 cannot be pushed by sleeve 411 toward the first chute 415，But the size of flange recess 411021 of the flange 41102 because of sleeve 411，Make the rotatable certain angle of sleeve 411，Therefore sleeve 411 can one direction rotate to an angle.

Then, it is this utility model the 4th embodiment electronic lock control mechanism lock hook lock housing back side perspective exploded view please refer to Figure 22 and Figure 23, Figure 22；Figure 23 is this utility model the 4th embodiment electronic lock control mechanism lock hook lock housing back side schematic perspective view.As shown in figure 22, in the 4th embodiment of the present utility model, lock hook lock housing 42 includes the 4201, second side, the first side 4202 and the 3rd side 4203, and the first side 4201 is run through lock hook hole 42011, perforation 42021 runs through the second side 4202, and perforation 42031 runs through the 3rd side 4203；Lock hook part 421 is rotatably disposed within lock hook lock housing 42, has snap fit 42101 extended retraction lock hook hole 42011, lock hook part 421 has guide groove 42102；There is in lock hook lock housing 42 follower lever chute 422, follower lever chute 422 houses follower lever 423 and the 5th spring 424, follower lever 423 has cylinder 42301, cylinder 42301 is located in the guide groove 42102 of lock hook part 421, in order to drive lock hook part 421 to rotate, the snap fit 42101 making lock hook part 421 stretches out retraction lock hook hole 42011, and the 5th spring 424 one end is resisted against the rear end of follower lever 423, and the other end is resisted against follower lever chute 422 inwall；Eccentric 425 is socketed in outside hollow axle tube 426, both synchronous rotaries；Hollow axle tube 426 front end 42601 is located in the perforation 42031 of the 3rd side 4203 of lock hook lock housing 42, hollow axle tube 426 rear end 42602 is located in the perforation 42021 of the second side 4202 of lock hook lock housing 42, wherein, the front end of follower lever 423 is resisted against in the outer rim of eccentric 425, as shown in figure 23, when hollow axle tube 426 band movable eccentric wheel 425 rotates, follower lever 423 i.e. moves up and down because abutting against eccentric 425, and when follower lever 423 moves up and down, the cylinder 42301 of follower lever 423 moves in the guide groove 42102 of lock hook part 421, and then drive the snap fit 42101 of lock hook part 421 to stretch out retraction lock hook hole 42011.

Then, please refer to Figure 24, for this utility model the 4th embodiment electronic lock control mechanism door inner lock shell front perspective exploded view.As shown in figure 24, in the 4th embodiment of the present utility model, door inner lock shell 43 includes the first side 4301 and the second side 4302, and the first side 4301 is provided with perforation 43011 in door, and the second side 4302 is provided with cage knob hole 43021；nullDominant control 431 has axially penetrated through through hole 43101，Dominant control 431 front end has protuberance 43102，There are on protuberance 43,102 two arcuation grooves 431021，Hollow axle tube 426 rear end has two arcuation projections 426021 (as shown in figure 23) corresponding with the arcuation groove 431021 of dominant control 431，The arcuation projection 426021 of hollow axle tube 426 rear end protrudes the perforation 42021 of the second side 4202 of lock hook lock housing 42 and corresponding the combining closely of arcuation groove 431021 of dominant control 431 protuberance 43102，Dominant control 431 and both hollow axle tubes 426 synchronous rotary，Dominant control 431 rear end indent forms accommodation space 43103，Accommodation space 43103 houses interlock plate 432、First pawl 433 and the second pawl 434，First pawl 433 and the second pawl 434 are rotatably disposed within dominant control 431，Interlock plate 432 has the first pawl groove 43201 and the second pawl groove 43202.

Then, it is this utility model the 4th embodiment electronic lock control mechanism interlock plate back side schematic perspective view please refer to Figure 24 to Figure 26, Figure 25；Figure 26 is this utility model the 4th embodiment electronic lock control mechanism dominant control back side schematic perspective view.As shown in figure 25, the first pawl groove 43201 can be withstood in the first pawl 433 front end, and the second pawl groove 43202 can be withstood in the second pawl 434 front end, makes interlock plate 432 cannot rotate toward direction of rotation 700 counterclockwise, but can rotate toward the direction 800 that turns clockwise；As shown in figure 26, there is in the accommodation space 43103 of dominant control 431 rear end the 3rd chute 431031 and the 4th chute 431032,3rd chute 431031 houses the 3rd spring 435,4th chute 431032 houses the 4th spring 436,3rd spring 435 one end is resisted against the side of the first pawl 433, the other end is resisted against the 3rd chute 431031 inwall, and the 4th spring 436 one end is resisted against the side of the second pawl 434, and the other end is resisted against the 4th chute 431032 inwall.

Then, referring to Figure 27 and Figure 28, Figure 27 is this utility model the 4th embodiment electronic lock control mechanism dominant control and cage knob perspective exploded view；Figure 28 is this utility model the 4th embodiment electronic lock control mechanism generalized section.As shown in figure 27, there are on dominant control 431 rear end two projections 43104, there are outside cage knob 437 two grooves 43701 corresponding with the projection 43104 of dominant control 431, corresponding the combining closely of groove 43701 of the projection 43104 of dominant control 431 and cage knob 437, make cage knob 437 and dominant control 431 synchronous rotary, and cage knob 437 and dominant control 431 combine after be placed in the cage knob hole 43021 of an inner lock shell 43；Interlock plate 432 central authorities are equipped with power transmission shaft rod aperture 43203, make transmission shaft lever 412 be combined with the power transmission shaft rod aperture 43203 of interlock plate 432, drive interlock plate 432 synchronous rotary；Then, refer to Figure 28, transmission shaft lever 412 front end is combined through the perforation 42031 of hollow axle tube 426 and the 3rd side 4203 of lock hook lock housing 42 with core 413, transmission shaft lever 412 rear end is combined through the perforation 42021 of the second side 4202 and the through hole 43101 of dominant control 431 of lock hook lock housing 42 with interlock plate 432, therefore core 413, transmission shaft lever 412 and interlock plate 432 three's synchronous rotary, and transmission shaft lever 412 is through hollow axle tube 426, both do not have synchronous rotary.

Then, referring to Figure 29 to Figure 31, Figure 29 is this utility model the 4th embodiment electronic lock control mechanism schematic rear view of lock housing outdoors when locking；Figure 30 is this utility model the 4th embodiment electronic lock control mechanism schematic rear view of lock hook lock housing when locking；Figure 31 is the schematic rear view of lock hook lock housing after this utility model the 4th embodiment electronic lock control mechanism unlocks.As shown in figure 29, when this utility model the 4th embodiment electronic lock control mechanism is locked, the flange recess 411021 of the flange 41102 of sleeve 411 is withstood in the front end of the first trip 416, limit sleeve 411 to rotate, same, the flange recess 411021 of the flange 41102 of sleeve 411 is withstood in the front end of the second trip 419, limits sleeve 411 and rotates, and the angular rim 4193 of the angular rim 4163 of the first trip 416 and the second trip 419 makes sleeve 411 can rotate toward clockwise 1000；As shown in figure 30, when this utility model the 4th embodiment electronic lock control mechanism is locked, the snap fit 42101 of lock hook part 421 stretches out in outside lock hook hole 42011, and follower lever 423 is up pushed up by eccentric 425 outer rim, and follower lever 423 compresses the 5th spring 424.

nullThis utility model the 4th embodiment electronic lock control mechanism，Key 414 can be used to unlock or lock，During unblock，Key 414 is inserted lockhole 41301，Make core 413 toward 1000 half rotation clockwise，As shown in figure 29，And core 413、Transmission shaft lever 412 and interlock plate 432 three's synchronous rotary，Therefore transmission shaft lever 412 and interlock plate 432 and then core 413 are toward 1000 half rotation clockwise，Then，Refer to Figure 25，When core 413 is toward 1000 half rotation clockwise (Figure 29)，Interlock plate 432 and then core 413 rotates (Figure 25) toward counterclockwise 700，Because the first pawl groove 43201 is withstood in the first pawl 433 front end，The second pawl groove 43202 is withstood in second pawl 434 front end，Therefore when interlock plate 432 rotates toward direction of rotation 700 counterclockwise，First pawl 433 and the second pawl i.e. push dominant control 431 synchronous axial system together，Represent dominant control 431 and interlock plate 432 synchronous rotary，Dominant control 431 rotates (Figure 26) toward the direction 1200 that turns clockwise，And dominant control 431 and hollow axle tube 426 synchronous rotary，Hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise，Hollow axle tube 426 then with eccentric 425 synchronous rotary，When eccentric 425 rotates toward the direction 1400 that turns clockwise，Follower lever 423 is promoted by the 5th spring 424 and moves down，And then make the snap fit 42101 of lock hook part 421 retract in lock hook hole 42011，Reach to unlock purpose，As shown in figure 31；nullAnd when unlocking，Equally key 414 is inserted lockhole 41301，Make core 413 toward 1000 half rotation clockwise，As shown in figure 29，And core 413、Transmission shaft lever 412 and interlock plate 432 three's synchronous rotary，Therefore transmission shaft lever 412 and interlock plate 432 and then core 413 are toward 1000 half rotation clockwise，Then，Refer to Figure 25，When core 413 is toward 1000 half rotation clockwise (Figure 29)，Interlock plate 432 and then core 413 rotates (Figure 25) toward counterclockwise 700，Because the first pawl groove 43201 is withstood in the first pawl 433 front end，The second pawl groove 43202 is withstood in second pawl 434 front end，Therefore when interlock plate 432 rotates toward direction of rotation 700 counterclockwise，First pawl 433 and the second pawl i.e. push dominant control 431 synchronous axial system together，Represent dominant control 431 and interlock plate 432 synchronous rotary，Dominant control 431 rotates (Figure 26) toward the direction 1200 that turns clockwise，And dominant control 431 and hollow axle tube 426 synchronous rotary，Hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise，Hollow axle tube 426 then with eccentric 425 synchronous rotary，When eccentric 425 rotates toward the direction 1400 that turns clockwise，The promotion of follower lever 423 eccentric 425 outer rim and up move，And then make the snap fit 42101 of lock hook part 421 stretch out lock hook hole 42011，Reach purpose of locking，As shown in figure 30.

nullThis utility model the 4th embodiment electronic lock control mechanism，The cage knob 437 that can use an inner lock shell 43 unlocks or locks，During unblock，By cage knob 437 toward 1600 half rotation clockwise，As shown in figure 27，Because of cage knob 437 and dominant control 431 synchronous rotary，Dominant control 431 is same rotates (Figure 26) toward the direction 1200 that turns clockwise，And dominant control 431 and hollow axle tube 426 synchronous rotary，Hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise，Hollow axle tube 426 then with eccentric 425 synchronous rotary，When eccentric 425 rotates toward the direction 1400 that turns clockwise，Follower lever 423 is promoted by the 5th spring 424 and moves down，And then make the snap fit 42101 of lock hook part 421 retract in lock hook hole 42011，Reach to unlock purpose，As shown in figure 31；And when locking, equally by cage knob 437 toward 1600 half rotation clockwise, as shown in figure 27, because of cage knob 437 and dominant control 431 synchronous rotary, dominant control 431 rotates (Figure 26) toward the direction 1200 that turns clockwise, and dominant control 431 and hollow axle tube 426 synchronous rotary, hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise, hollow axle tube 426 then with eccentric 425 synchronous rotary, when eccentric 425 rotates toward the direction 1400 that turns clockwise, the promotion of follower lever 423 eccentric 425 outer rim and up move, and then make the snap fit 42101 of lock hook part 421 stretch out lock hook hole 42011, reach purpose of locking, as shown in figure 30.

Then, the schematic rear view of lock housing outdoors when Figure 29 and Figure 32, Figure 32 are the unblock of this utility model the 4th embodiment electronic lock control mechanism is referred to.nullWhen this utility model the 4th embodiment electronic lock control mechanism is locked，It is used as remote controller to unlock，During unblock，Sleeve 411 is rotated by the knob outdoors 41101 first with sleeve 411 toward clockwise 1000，As shown in figure 29，Second trip 419 is pushed in the second chute 418 by the flange recess 411021 making the flange 41102 of sleeve 411 along the angular rim 4193 of the second trip 419，Now，The second spring 4110 is pushed down in first rear end 4191 of the second trip 419，Second rear end 4192 of the second trip 419 presses microswitch 4111，As shown in fig. 21b，The proving program of microswitch 4111 start-up circuit module 4112 is verified，After being proved to be successful，Actuator 4113 i.e. rotarily drives lock pin 4114 upwards，No longer block the first trip 416，Make the first trip 416 cannot limit sleeve 411 again to rotate，Then sleeve 411 is rotated toward clockwise 1000，Because the first trip 416 is not kept off by lock pin 4114，The flange recess 411021 of the flange 41102 of sleeve 411 cannot be withstood，Sleeve 411 can be smoothly toward 1000 half rotation clockwise，Core 413 and sleeve 411 synchronous rotary simultaneously，And core 413、Transmission shaft lever 412 and interlock plate 432 three's synchronous rotary，Therefore transmission shaft lever 412 and interlock plate 432 and then core 413 are toward 1000 half rotation clockwise，Then，Refer to Figure 25，When core 413 is toward 1000 half rotation clockwise (Figure 29)，Interlock plate 432 and then core 413 rotates (Figure 25) toward counterclockwise 700，Because the first pawl groove 43201 is withstood in the first pawl 433 front end，The second pawl groove 43202 is withstood in second pawl 434 front end，Therefore when interlock plate 432 rotates toward direction of rotation 700 counterclockwise，First pawl 433 and the second pawl i.e. push dominant control 431 synchronous axial system together，Represent dominant control 431 and interlock plate 432 synchronous rotary，Dominant control 431 rotates (Figure 26) toward the direction 1200 that turns clockwise，And dominant control 431 and hollow axle tube 426 synchronous rotary，Hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise，Hollow axle tube 426 then with eccentric 425 synchronous rotary，When eccentric 425 rotates toward the direction 1400 that turns clockwise，Follower lever 423 is promoted by the 5th spring 424 and moves down，And then make the snap fit 42101 of lock hook part 421 retract in lock hook hole 42011，Reach to unlock purpose，As shown in figure 31；nullAfter unblock，As being intended to lock，Sleeve 411 is rotated by the knob outdoors 41101 also with sleeve 411 toward clockwise 1000，As shown in figure 29，Second trip 419 is pushed in the second chute 418 by the flange recess 411021 making the flange 41102 of sleeve 411 along the angular rim 4193 of the second trip 419，Now，The second spring 4110 is pushed down in first rear end 4191 of the second trip 419，Second rear end 4192 of the second trip 419 presses microswitch 4111，As shown in fig. 21b，The proving program of microswitch 4111 start-up circuit module 4112 is verified，After being proved to be successful，Actuator 4113 i.e. rotarily drives lock pin 4114 upwards，No longer block the first trip 416，Make the first trip 416 cannot limit sleeve 411 again to rotate，Then sleeve 411 is rotated toward clockwise 1000，Because the first trip 416 is not kept off by lock pin 4114，The flange recess 411021 of the flange 41102 of sleeve 411 cannot be withstood，Sleeve 411 can be smoothly toward 1000 half rotation clockwise，Core 413 and sleeve 411 synchronous rotary simultaneously，And core 413、Transmission shaft lever 412 and interlock plate 432 three's synchronous rotary，Therefore transmission shaft lever 412 and interlock plate 432 and then core 413 are toward 1000 half rotation clockwise，Then，Refer to Figure 25，When core 413 is toward 1000 half rotation clockwise (Figure 29)，Interlock plate 432 and then core 413 rotates (Figure 25) toward counterclockwise 700，Because the first pawl groove 43201 is withstood in the first pawl 433 front end，The second pawl groove 43202 is withstood in second pawl 434 front end，Therefore when interlock plate 432 rotates toward direction of rotation 700 counterclockwise，First pawl 433 and the second pawl i.e. push dominant control 431 synchronous axial system together，Represent dominant control 431 and interlock plate 432 synchronous rotary，Dominant control 431 rotates (Figure 26) toward the direction 1200 that turns clockwise，And dominant control 431 and hollow axle tube 426 synchronous rotary，Hollow axle tube 426 rotates (Figure 30) toward the direction 1400 that turns clockwise，Hollow axle tube 426 then with eccentric 425 synchronous rotary，When eccentric 425 rotates toward the direction 1400 that turns clockwise，Follower lever 423 is up moved by the promotion of eccentric 425 outer rim，And then make the snap fit 42101 of lock hook part 421 stretch out lock hook hole 42011，Reach purpose of locking，As shown in figure 30；During unblock, sleeve 411 is rotated toward clockwise 1000, making the second trip 419 press microswitch 4111 start-up circuit module 4112 to verify, after being proved to be successful, actuator 4113 rotarily drives lock pin 4114, after fixing number of seconds, actuator 4113 is auto-reverse, makes lock pin 4114 downwards, blocks the first trip 416, first trip 416 withstands the flange recess 411021 of the flange 41102 of sleeve 411, makes sleeve 411 to rotate to an angle；In like manner, when locking, sleeve 411 is rotated toward clockwise 1000, makes the second trip 419 press microswitch 4111 start-up circuit module 4112 and verify, after being proved to be successful, actuator 4113 rotarily drives lock pin 4114, and after fixing number of seconds, actuator 4113 is auto-reverse, make lock pin 4114 downward, blocking the first trip 416, the first trip 416 withstands the flange recess 411021 of the flange 41102 of sleeve 411, makes sleeve 411 to rotate to an angle.When 4th embodiment electronic lock 4 controlling organization of the present utility model uses remote controller unlock and lock, sleeve 411 direction of rotation is identical, such as: during unblock, dextrorotation rotaring sleeve 411 2 times, when locking, same also dextrorotation rotaring sleeve 411 2 times, is not required to as first, second embodiment needs bidirectional rotary unlock or lock, and operation seems relatively intuition.

When this utility model first to fourth embodiment electronic lock control mechanism is locked, remote controller and circuit module can be used to carry out electronically validating, it is used as mobile phone and carries out electronically validating with circuit module, or use shaking sensor, tap door-plate and carry out electronically validating with circuit module, and then control actuator is unlocked, do not limit at this this utility model, it addition, actuator can be electric magnet or motor, do not limit at this this utility model.

In sum, through the electronic lock control mechanism that the utility model proposes, having electronic lock and two kinds of locked mechanisms of key lock on electronic lock, user is optional uses key or electronic type to unblank simultaneously；And dead bolt is driven by core, actuator only is used for limiting the rotation of sleeve, imply that user when using electronic type to unblank, electronic lock mechanism relatively can reach the effect of power saving；Furthermore sleeve and core are a cylinder moulding, and the volume exposing to lock housing is little, and door-plate only need to have circular hole, the installation for lockset is the simplest with processing.

Preferred embodiment provided above; the purpose of this utility model, technical scheme and advantage are further described; it is it should be understood that; the foregoing is only preferred embodiment of the present utility model; it is not limited to this utility model; all in spirit of the present utility model and principle, that made any amendment, equivalent and improvement etc., should be included in the interior of protection domain of the present utility model.

Claims (12)

1. an electronic lock control mechanism, it is characterised in that:

Lock housing, comprises the first side and the second side, and described first side is run through a dead bolt hole, and described second side is run through sleeve hole；

Dead bolt, is located in described dead bolt hole movably linearly, and described dead bolt has dead bolt breach；

Sleeve, is located in described sleeve hole, and described sleeve rear end is provided with flange, and described flange outer sides is provided with at least one flange recess, and described sleeve is axially equipped with lock core hole；

Core, has lockhole, and described core is located in described lock core hole and end has eccentric convex cylindrical, and described bias convex cylindrical is installed in described dead bolt breach, is used for driving described dead bolt to move；

Chute, is located in described lock housing, is used for housing trip and elastic parts, described elastic parts one end is resisted against the first rear end of described trip, the other end is resisted against described chute inwall, and described trip front end is for withstanding the described flange recess of described sleeve, for limiting the rotation of described sleeve；

Microswitch, in being located at described lock housing and is connected with circuit module, and described trip presses described microswitch, and described microswitch starts the proving program of described circuit module；And

Actuator, is located in described lock housing, blocks described trip for band pendulum lock pin, makes described trip cannot withstand the described flange recess of described sleeve, and described sleeve can arbitrarily rotate；

Wherein, described trip front end has at least one angular rim, described trip is pushed in described chute along the described angular rim of described trip for the described flange recess that makes described sleeve, described elastic parts is pushed down in described first rear end making described trip, and the second rear end of described trip presses described microswitch.

2. electronic lock control mechanism as claimed in claim 1, it is characterised in that described elastic parts is spring.

3. an electronic lock control mechanism, it is characterised in that；

Lock housing, includes the first side and the second side, and described first side is run through dead bolt hole, and described second side is run through sleeve hole；

Dead bolt, is located in described dead bolt hole movably linearly, and described dead bolt has dead bolt breach；

Sleeve, is located in described sleeve hole, and described sleeve rear end is provided with flange, and described flange outer sides is provided with at least one flange recess, and described sleeve is axially equipped with lock core hole；

Core, has lockhole, and described core is located in described lock core hole and end has eccentric convex cylindrical, and described bias convex cylindrical is installed in described dead bolt breach, is used for driving described dead bolt to move；

First chute and the second chute, it is located in described lock housing, and described first chute and described second chute homonymy are arranged, described first chute houses trip and the first elastic parts, described first elastic parts one end is resisted against the rear end of described trip, the described first elastic parts other end is resisted against described first chute inwall, and described trip front end is for withstanding the described flange recess of described sleeve, for limiting the rotation of described sleeve；Described second chute houses moving part and the second elastic parts, described second elastic parts one end is resisted against the first rear end of described moving part, the described second elastic parts other end is resisted against described second chute inwall, and described moving part front end is resisted against the described eccentric convex cylindrical of described core；

Microswitch, in being located at described lock housing and is connected with circuit module, and described moving part presses described microswitch, and described microswitch starts the proving program of described circuit module；And

Actuator, is located in described lock housing, blocks described trip for band pendulum lock pin, makes described trip cannot withstand the described flange recess of sleeve, and described sleeve can arbitrarily rotate；

Wherein, described trip front end has at least one angular rim, for making the described flange recess of described sleeve be pushed in described first chute by described trip along the described angular rim of described trip；

Wherein, the described eccentric convex cylindrical of described core promotes described moving part, makes described first rear end of described moving part push down described second elastic parts, and the second rear end of described moving part presses described microswitch.

4. electronic lock control mechanism as claimed in claim 3, it is characterised in that described first elastic parts and described second elastic parts are all spring.

5. an electronic lock control mechanism, it is characterised in that；

Lock housing, includes the first side and the second side, and described first side is run through dead bolt hole, and described second side is run through sleeve hole；

Dead bolt, is located in described dead bolt hole movably linearly, and described dead bolt has dead bolt breach；

Sleeve, is located in described sleeve hole, and described sleeve rear end is provided with flange, and described flange outer sides is provided with at least one flange recess, and described sleeve is axially equipped with lock core hole；

Core, has lockhole, and described core is located in described lock core hole and end has eccentric convex cylindrical, and described bias convex cylindrical is installed in described dead bolt breach, is used for driving described dead bolt to move；

First chute and the second chute, it is located in described lock housing, and described first chute and described second chute are oppositely arranged, described first chute houses the first trip and the first elastic parts, described first elastic parts one end is resisted against the first rear end of described first trip, the described first elastic parts other end is resisted against described first chute inwall, described first trip front end is for withstanding the described flange recess of described sleeve, for limiting the rotation of described sleeve, described second chute houses the second trip and the second elastic parts, described second elastic parts one end is resisted against the first rear end of described second trip, the described second elastic parts other end is resisted against described second chute inwall；

Microswitch, in being located at described lock housing and is connected with circuit module, and described second trip presses described microswitch, and described microswitch starts the proving program of described circuit module；And

Actuator, is located in described lock housing, blocks described first trip for band pendulum lock pin, makes described first trip withstand the described flange recess of described sleeve, and described sleeve cannot arbitrarily rotate；

Wherein, described first trip has two angular rim, for making the described flange recess of described sleeve be pushed in described first chute by described first trip along described first trip angular rim；

Wherein, described second trip has two angular rim, described second trip is pushed in described second chute by the described flange recess for making described sleeve along described second trip angular rim, described second elastic parts is pushed down in described first rear end making described second trip, and the second rear end of described second trip presses described microswitch.

6. electronic lock control mechanism as claimed in claim 5, it is characterised in that described first elastic parts and described second elastic parts are all spring.

7. an electronic lock control mechanism, it is characterised in that；

Lock housing outdoors, described lock housing outdoors runs through and is provided with sleeve hole；

Sleeve, is located in described sleeve hole, and described barrel forward end is knob outdoors, and described sleeve middle-end is provided with flange, and described flange outer sides is provided with at least one flange recess, and described sleeve is axially equipped with lock core hole；

Core, is located in described lock core hole and has lockhole；

First chute and the second chute, it is located in described lock housing, and described first chute and described second chute are oppositely arranged, described first chute houses the first trip and the first elastic parts, described first elastic parts one end is resisted against the first rear end of described first trip, the described first elastic parts other end is resisted against described first chute inwall, described first trip front end is for withstanding the described flange recess of described sleeve, for limiting the rotation of described sleeve, described second chute houses the second trip and the second elastic parts, described second elastic parts one end is resisted against the first rear end of described second trip, the described second elastic parts other end is resisted against described second chute inwall；

Microswitch, be located at described in lock housing and is connected with circuit module outdoors, and described second trip presses described microswitch, the proving program of the described microswitch described circuit module of startup；And；

Actuator, be located at described in outdoors in lock housing, block described first trip for band pendulum lock pin, make described first trip withstand the described flange recess of described sleeve, described sleeve cannot arbitrarily rotate；

Lock hook lock housing, be set in parallel in described in outdoors after lock housing, include the first side, the second side and the 3rd side, described first side is run through lock hook hole, and has a perforation to run through described second side and described 3rd side；

Lock hook part, is rotatably disposed within described lock hook lock housing and has the extended retraction of snap fit described lock hook hole, described lock hook part has guide groove；

Follower lever chute, it is located in described lock hook lock housing, for housing follower lever and the 5th elastic parts, described follower lever has cylinder, described cylinder is located in the described guide groove of described lock hook part, is used for driving described lock hook part to rotate, and makes the described snap fit of described lock hook part stretch out the described lock hook hole of retraction, described 5th elastic parts one end is resisted against the rear end of described follower lever, and the other end is resisted against described follower lever chute inwall；

Eccentric is socketed in outside hollow axle tube, both synchronous rotaries, described hollow axle tube front end is located in the described perforation of described 3rd side of described lock hook lock housing, described hollow axle tube rear end is located in the described perforation of described second side of described lock hook lock housing, wherein, the front end of described follower lever is resisted against in the outer rim of described eccentric；

Door inner lock shell, after being set in parallel in described lock hook lock housing, described door inner lock shell includes the first side and the second side, and described first side is provided with perforation in door, and described second side is provided with cage knob hole；

nullDominant control，Axially penetrate through through hole，Described dominant control front end has protuberance，For affixed with described hollow axle tube rear end，Described dominant control rear end indent forms accommodation space，For housing interlock plate、First pawl and the second pawl，Described first pawl and described second pawl are rotatably disposed within described dominant control，Described interlock plate has the first pawl groove and the second pawl groove，Described first pawl groove can be withstood in described first pawl front end，Described second pawl groove can be withstood in described second pawl front end，Described interlock plate is made to rotate，There is in described accommodation space the 3rd chute and the 4th chute，Described 3rd chute houses the 3rd elastic parts，Described 4th chute houses the 4th elastic parts，Described 3rd elastic parts one end is resisted against described first pawl side，The described 3rd elastic parts other end is resisted against described 3rd chute inwall，Described 4th elastic parts one end is resisted against described second pawl side，The described 4th elastic parts other end is resisted against described 4th chute inwall；

Cage knob, is placed in the described cage knob hole of described door inner lock shell, affixed with described dominant control, described cage knob and described dominant control synchronous rotary；And

Transmission shaft lever, front end is affixed with described core rear end through the described perforation of described hollow axle tube and described 3rd side of described lock hook lock housing, and described transmission shaft lever rear end is affixed with described interlock plate through the described perforation of described second side of described lock hook lock housing and the described through hole of described dominant control；Wherein, described first trip has angular rim, for making the described flange recess of described sleeve be pushed in described first chute by described first trip along described first trip angular rim；

Wherein, described second trip has angular rim, described second trip is pushed in described second chute by the described flange recess for making described sleeve along described second trip angular rim, described elastic parts is pushed down in described first rear end making described second trip, and the second rear end of described second trip presses described microswitch.

8. electronic lock control mechanism as claimed in claim 7, it is characterised in that described first elastic parts, described second elastic parts, described 3rd elastic parts, described 4th elastic parts and described 5th elastic parts are all spring.

9. electronic lock control mechanism as claimed in claim 7, it is characterized in that, there is on the described protuberance of described dominant control at least one arcuation groove, described hollow axle tube rear end has the arcuation projection that at least one is corresponding with the described arcuation groove of described dominant control, and described arcuation projection protrudes the described perforation of described second side of described lock hook lock housing and described corresponding the combining closely of arcuation groove of described dominant control.

10. electronic lock control mechanism as claimed in claim 7, it is characterized in that, on described dominant control rear end, there is at least one projection, there is at least one groove corresponding with the projection of described dominant control, corresponding the combining closely of described groove of the described projection of described dominant control and described cage knob outside described cage knob.

11. electronic lock control mechanisms as claimed in claim 7, it is characterised in that described interlock plate central authorities are equipped with power transmission shaft rod aperture, and described transmission shaft lever may pass through described power transmission shaft rod aperture and drives described interlock plate synchronous rotary.

12. electronic lock control mechanisms as claimed in claim 7, it is characterised in that described core rear end has a groove corresponding with described transmission shaft lever front end geometry, are used for making described core combine closely with described transmission shaft lever front end.