The present invention relates to an electronic cylinder lock.
A conventional cylinder lock mainly has a main body. The main body is provided with a rotary cam. Two opposite sides of the main body are provided with an inner knob and an outer knob, respectively. The inner knob is connected to the rotary cam. The outer knob is connected to the rotary cam through an engaging mechanism. The engaging mechanism generally has a first engaging member disposed on the rotary cam, a second engaging member disposed on the outer knob, and a driving member that can drive the first engaging member to engage with or disengage from the second engaging portion. Therefore, when the cylinder lock is in a locked state, the driving member drives the first engaging member to disengage from the second engaging member, so that the outer knob is idling and cannot drive the rotary cam to perform unlocking. When the cylinder lock is in an unlocked state, the driving member drives the first engaging member to engage with the second engaging member, so that the outer knob can drive the rotary cam to perform unlocking.
However, the aforementioned cylinder lock has the following disadvantages. Firstly, the driving member uses a pushing means to push the first engaging member toward the second engaging member, so that the first engaging member is engaged with the second engaging member. Therefore, the second engaging member has a tendency to be pushed away from the first engaging member, resulting in that the first engaging member cannot be reliably engaged with the second engaging member, that is, the engagement is incomplete or the first engaging member is not engaged with the second engaging member, so that the outer knob cannot drive the rotary cam to perform unlocking. Secondly, because the driving member is disposed in the main body, the driving member is limited by the space of the main body. Only a smaller motor can be used, resulting in insufficient output of the driving member, and the first engaging member cannot be effectively driven. Thirdly, a control module disposed in the first knob and a read head disposed in the second knob will be blocked by the driving member disposed in the main body, which is inconvenient for power connection and signal connection between the two. Accordingly, the inventor of the present invention has devoted himself based on his many years of practical experiences to solve these problems.
The primary object of the present invention is to provide an electronic cylinder lock, which uses a pulling means to perform locking and unlocking, thereby improving the joint stability of an engaging mechanism.
In order to achieve the aforesaid object, the present invention provides an electronic cylinder lock comprising a main body. The main body has a shaft hole and a notch communicating with the shaft hole. A rotary cam is rotatably disposed in the notch. A first shaft and a second shaft are insertedly connected to two ends of the shaft hole of the main body. One end of the first shaft, inserted into the shaft hole, is provided with a first engaging portion. Another end of the first shaft is provided with a first coupling portion. The first shaft has an axial first through hole therein. The first through hole passes through the first engaging portion and the first coupling portion. One end of the second shaft, inserted into the shaft hole, is provided with a second engaging portion. Another end of the first shaft is provided with a second coupling portion. A control lever is inserted in the first through hole. One end of the control lever is connected to the second shaft. Another end of the control lever is provided with a driving portion. A first knob is connected to the first coupling portion. A second knob is connected to the second coupling portion. The electronic cylinder lock further comprises a control unit. The control unit has a driving source accommodated in the first knob. The driving source is connected to the driving portion for driving the control lever to link the second shaft to slide axially relative to the shaft hole, so that the second engaging portion is selectively disengaged from or engaged with the first engaging portion.
In the electronic cylinder lock provided by the present invention, the driving member adopts a pulling means, and the second shaft is pulled toward the first shaft through the control lever, so that the second engaging portion is engaged with the first engaging portion. Therefore, the second engaging portion has a tendency to approach the first engaging portion, which can ensure that the second engaging portion is indeed engaged with the first engaging portion to improve the stability of the engagement.
Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings.
The main body 10 has a first side 11, a second side 12 opposite to the first side 11, and a circumferential side 13 connected between the first side 11 and the second side 12. The main body 10 has a shaft hole 14 passing through the first side 11 and the second side 12. The first side 11 is formed with a corresponding first opening 141, and the second side 12 is formed with a corresponding second opening 142. The circumferential side 13 of the main body 10 is formed with a notch 15 communicating with the shaft hole 14 and a limiting hole 16 communicating with the shaft hole 14. A limiting pin 161 is provided in the limiting hole 16.
The rotary cam 20 is accommodated in the notch 15. The rotary cam 20 has a connecting hole 21 corresponding to the shaft hole 14. The circumferential side of the rotary cam 20 is provided with a raised portion 22. The raised portion 22 has a fixing hole 23 communicating with the connecting hole 21. A fixing pin 231 is provided in the fixing hole 23.
The first shaft 30 is inserted in the shaft hole 14 from the first opening 141. The outer wall of the first shaft 30 is formed with an annular limiting groove 31 corresponding to the limiting pin 161. The limiting pin 161 is confined in the annular limiting groove 31, so that the first shaft 30 can only rotate relative to the shaft hole 14. One end of the first shaft 30 is inserted into the shaft hole 14 and the connecting hole 21 of the rotary cam 20 and is provided with a first engaging portion 32. One end of the fixing pin 231 is inserted into the connecting hole 21 and is pressed against the outer wall of the first shaft 30, so that the first shaft 30 is connected to the rotary cam 20, and the first shaft 30 can drive the rotary cam 20 to rotate. The other end of the first shaft 30 is provided with a first coupling portion 33. The outer side of the first coupling portion 33 is recessed to form a rotation trough 331. The first shaft 30 has an axial first through hole 34 therein. The first through hole 34 passes through the first engaging portion 32 and the first coupling portion 33.
The second shaft 40 is inserted in the shaft hole 14 from the second opening 142 and can rotate and slide axially relative to the shaft hole 14. One end of the second shaft 40, inserted into the shaft hole 14, is provided with a second engaging portion 41 corresponding to the first engaging portion 32. The second engaging portion 41 is engagable with the first engaging portion 32, so that the second shaft 40 can drive the first shaft 30 to rotate. In this embodiment, the first engaging portion 32 is composed of a plurality of spaced protrusions, and the second engaging portion 41 is composed of a plurality of spaced notches. The other end of the first shaft 40 is provided with a second coupling portion 42. The second shaft 40 has an axial second through hole 43 therein. The second through hole 43 passes through the second engaging portion 41 and the second coupling portion 42. Furthermore, the outer wall of the second shaft 40 is formed with at least one first perforation 44 communicating with the second through hole 43.
The control lever 50 is inserted in the first through hole 34 of the first shaft 30 and can slide axially relative to the first shaft 30. One end of the control lever 50 is inserted through the first engaging portion 32 into the second through hole 43, and is formed with at least one second perforation 51 corresponding to the first perforation 44, and is provided with at least one connecting pin 52. The connecting pin 52 is inserted through the corresponding first perforation 44 and the corresponding second perforation 51, so that the control lever 50 is connected to the second shaft 40 and can drive the second shaft 40 to slide axially relative to the shaft hole 14. In addition, the other end of the control lever 50 is provided with a driving portion 53. The driving portion 53 is rotatably accommodated in the rotation trough 331. The outer wall of the control lever 50 is provided with an axial slot 54.
The first knob 60 is connected to the first coupling portion 33 and configured to drive the first shaft 30 to rotate relative to the shaft hole 14. The first knob 60 has a first housing 61. A first accommodating space 62 is defined in the first housing 61 for accommodating the first coupling portion 33. The opening of the first accommodating space 62 is sealed by a first cover 63, so that the first knob 60 is connected to the first coupling portion 33.
The second knob 70 is connected to the second coupling portion 42 and configured to drive the second shaft 50 to rotate relative to the shaft hole 14. The second knob 70 has a second housing 71. A second accommodating space 72 is defined in the second housing 71 for accommodating the second coupling portion 42. The opening of the second accommodating space 72 is sealed by a second cover 73, so that the second knob 70 is connected to the second coupling portion 42.
The control unit 80 has a driving base 81 accommodated in the first accommodating space 62. A driving source 82, such as a motor, is mounted on the driving base 81. The driving source 82 is connected to the driving portion 53 of the control lever 50 for driving the control lever 50 to slide axially relative to the first shaft 30. The control unit 80 further has a control assembly 83 such as a circuit board and a power supply, and a read head 84 disposed in the second accommodating space 72, and at least one lead wire 85. One end of the lead wire 85 is connected to the control assembly 83, and the other end of the lead wire 85 is inserted through the slot 54 of the control lever 50 and the second through hole 43 of the second shaft 40 and connected to the read head 84.
Although particular embodiments of the present invention have been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the present invention. Accordingly, the present invention is not to be limited except as by the appended claims.
Number | Date | Country | Kind |
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109102374 | Jan 2020 | TW | national |
Number | Name | Date | Kind |
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20040040355 | Goldman | Mar 2004 | A1 |
Number | Date | Country |
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0962610 | Dec 1999 | EP |
WO-2018156024 | Aug 2018 | WO |
Number | Date | Country | |
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20210222462 A1 | Jul 2021 | US |