CN206220685U - An electric mechanism for a locking device - Google Patents

Abstract

The utility model relates to a locking device, more specifically, to an electric mechanism for the locking device, which comprises: a motor, a transmission shaft arranged on the motor shaft, a coil spring arranged on the transmission shaft, and also comprises: a follower shaft which can be axially displaced in the coil spring, a pin arranged on the follower shaft which can be screwed into the coil spring, the follower shaft extending into the coil spring and slidingly cooperating with the coil spring. Compared with the prior art solution, the follower shaft of the utility model always maintains a state of radial constraint on the cylindrical spring during the rotation of the cylindrical spring and the axial displacement of the follower column, effectively overcoming the vibration problem caused by the rotation of the spring.

Description

An electric mechanism for a locking device

technical field

The utility model relates to a locking device, and more particularly relates to an electric mechanism for a locking device with electronic control.

Background technique

Existing locking devices with electronic control generally adopt a locking mechanism driven by a micro DC motor. One of the technical solutions is to use a coil spring sleeved on the shaft and a pin fixed on the shaft to convert the rotational motion of the motor into a linear motion between the spring and the pin, and then push or pull a blocking element to control The deadbolt retracts.

For the scheme that adopts the pin rotation, when the pin moves relative to the spring helical line, the spring is compressed by the pin pressure, which generates a large friction, which in turn produces a force that makes the spring rotate with the shaft , It is easy to cause the spring to rotate with the shaft and run out radially, so that the spring cannot move smoothly in the axial direction, which not only causes wear between the spring and the slider, but also causes the pin to fail to enter the spring spiral track smoothly. In addition, the contact friction between the pin and the spring causes wear on the pin and the spring. Chinese utility model patent CN201110244325.0 discloses a technical scheme in which the pin rotates to push the axial displacement of the spring, and then pushes a blocking element to extend and retract, and proposes to set up the third winding of the spring to absorb the vibration and bounce of the spring. It is a technical measure to buffer the vibration and impact of the pin on the spring when the motor starts and turns, and prevent the spring from twisting or jumping.

It is also possible to fix the coil spring on the motor drive shaft to rotate with the motor, and fix the column pin on an axially slidable blocking element, which can also be pushed or pulled to extend to the locked position or retracted to the open position. Location. For example, the US Patent No. 5,628,216 granted by the applicant Schlage Lock Company discloses a locking device, which is arranged in the door lock and includes a motor, a gear set connected with the motor, a guide shaft connected with the gear set, a A cylindrical helical spring whose free end is fixed on the guide shaft. The helical spring can partly extend into a plunger sleeve arranged on the same axis. The pin is inserted vertically on the plunger sleeve. The spring of the tube passes between two adjacent turns. As the motor drives the helical spring to rotate, the pin is screwed into two adjacent turns of the helical spring, so that the plunger sleeve slides along the motor axis between the locked position and the unlocked position, thereby realizing the locking and unlocking control of the door lock.

This patent also discloses another locking device for door locks. The difference between this device and the above-mentioned technical solution is that in this solution, the pin is arranged on a frame protruding from the end of a locking plate, and the coil spring passes through the frame. The pin is inserted between two adjacent coils of the spring, and the locking plate is axially displaced between the locking position and the unlocking position under the action of the screwing of the spring and the pin.

The technical solution disclosed in the above-mentioned patent has the advantage that since the spring is fixed to the transmission shaft, the moment of inertia is small, and there is no problem of spring heel rotation and radial runout. But there are also unsatisfactory places, for example, due to the large volume and weight of the load (plunger sleeve and locking plate), when the spring is screwed into the pin, the friction force of the position where the spring contacts the pin due to being stretched Increase, easy to cause wear and tear of the spring and pin.

In addition, in some electric mechanisms, it is necessary to have a long spring with one end fixed and the other end not fixed. In this case, the part farther from the drive shaft will produce an off-axis throw when it rotates due to no radial constraints. cause the spring to vibrate.

It can be seen that, aiming at the technical subject of "the interaction between the pin and the coil spring, the rotational motion of the motor is converted into the linear motion between the coil spring and the pin, and then a blocking element is pushed or pulled to control the locking device", for There is a need for further improvements in motor mechanisms for locking devices.

Contents of the invention

The purpose of the utility model is to provide an electric mechanism for a locking device which can prevent the spring from vibrating due to rotation and reduce the friction between the pin and the spring.

Content of the present utility model comprises:

An electric mechanism for a locking device, comprising: a motor, a transmission shaft arranged on the motor shaft, and a coil spring arranged on the transmission shaft, and is characterized in that: it also includes: a The follower shaft of the displacement is a pin that can be screwed into the coil spring on the follower shaft, and the follower shaft stretches into the coil spring and is slidably matched with the coil spring.

Wherein, the coil spring is a cylindrical spring, and the cylindrical spring includes a screw-in portion and a buffer portion, and the pin is axially displaced within the range of the screw-in portion.

Wherein, the pitch of the buffer portion is zero, and the pitch of the screw-in portion is greater than the diameter of the pin.

Wherein, the unilateral gap between the outer diameter of the follower shaft and the inner diameter of the cylindrical spring is 0.15mm-0.30mm, and the pitch of the screw-in part is 1.1-1.3 times the diameter of the pin.

Wherein, the two free ends of the cylindrical spring are respectively provided with a first fixed ring and a second fixed ring, a first U-shaped bend connected with the first fixed ring, and a second U-shaped bend connected with the second fixed ring. ; The drive shaft is provided with an annular convex strip, the annular convex strip includes a convex strip head that matches the first U-shaped bend, the first U-shaped bend is sleeved on the convex strip head, and the first fixing ring is mounted on the annular Rib outside.

Wherein, the end of the follower shaft is provided with an elliptical column protruding from the outer circular surface of the follower shaft.

Wherein, the transmission shaft includes a first shaft shoulder and a second shaft shoulder, and includes a fixing frame arranged between the transmission shaft and the motor casing, and the fixing frame includes two fixing rods fixed on the bottom of the motor casing and a shaft perpendicular to the bottom of the motor casing. A third U-shaped bend of the fixed rod, the third U-shaped bend located between the first shoulder and the second shoulder to limit the axial displacement of the transmission shaft.

Wherein, the fixing frame is formed by bending a steel wire, and the diameter of the third U-shaped bend is smaller than the first shoulder and larger than the second shoulder.

Wherein, the motor shaft is a flat shaft, and the transmission shaft includes a flat shaft hole matched with the flat shaft.

Wherein, the follower shaft includes a pin hole, and the pin includes a head located between two adjacent coils of the coil spring and a tail fixed to the pin hole.

By adopting the technical solution of the utility model, the following beneficial technical effects can be obtained:

1. Compared with the existing technical solutions, the follower shaft of the utility model always maintains the state of radial constraint on the cylindrical spring during the rotation of the cylindrical spring and the axial displacement of the follower column, effectively overcoming the vibration caused by the rotation of the spring question.

2. The utility model adopts the structure that the buffer part is arranged on the cylindrical spring. When the column pin moves axially relative to the cylindrical spring, the buffer part is also stretched, so that the screw-in part of the spring is stretched and compressed. The reduction can effectively reduce the friction between the pin and the spring, thereby reducing the wear of the parts.

3. The technical solution of the utility model uses few parts, has a simple structure, and is easy to process and install.

Description of drawings

Fig. 1 is a three-dimensional structure diagram of an embodiment of the utility model.

Fig. 2 is an exploded schematic view of the three-dimensional structure of the embodiment of the present invention.

Fig. 3 is a schematic diagram of a three-dimensional structure of a cylindrical spring according to an embodiment of the present invention.

Fig. 4 is a schematic diagram of the three-dimensional structure of the transmission shaft of the embodiment of the utility model.

Fig. 5 is a perspective view of the three-dimensional structure of the transmission shaft of the embodiment of the present invention.

Fig. 6 is a schematic perspective view of the three-dimensional structure of the follower shaft of the embodiment of the present invention.

Fig. 7 is a schematic diagram of the assembly structure of the driving lever in the locked position in the panel device according to the embodiment of the present invention.

Fig. 8 is a schematic diagram of the assembly structure of the driving lever in the open position in the panel device according to the embodiment of the present invention.

detailed description

In order to allow those skilled in the art to further understand the utility model, the utility model will be described in detail below in conjunction with the accompanying drawings and embodiments.

Fig. 1 and Fig. 2 have shown the preferred embodiment structure of the present utility model, as shown in Fig. 1 and Fig. 2, electric mechanism comprises motor 10, transmission shaft 30, cylindrical spring 20, follower shaft 40, pin 60. The motor 10 is a common DC motor. The transmission shaft 30 and the motor shaft 11 adopt flat shaft cooperation to transmit torque, and the motor shaft 11 and the shaft hole 35 of the transmission shaft are fixed by interference fit. The two free ends of the cylindrical spring 20 are arranged as a first fixed ring 21 and a second fixed ring 22 around 1-2 turns, and the shapes connected with the first fixed ring 21 and the second fixed ring 22 are two directions opposite to each other. And the first U-shaped bend 23 and the second U-shaped bend 24 of the same size. The transmission shaft 30 is provided with an unclosed annular raised bar 31, which includes two raised bar heads 32, wherein one of the raised bar heads coincides with the first U-shaped bend 23, and the first U-shaped bent 23 Just can be embedded in a convex head 32, the first fixed ring 21 is sleeved on the outside of the convex head 32, the axial displacement of the cylindrical spring 20 is limited by the annular convex 31, the radial direction of the cylindrical spring 20 relative to the transmission shaft 30 The displacement is limited by the first U-bend 23 and the head 32 of the rib. The pin 60 can be arranged on the follower column 40 in such a way that two pin heads protrude symmetrically from the outer circle of the follower shaft 40, or one pin head protrudes in one direction, which method depends on For the object driven by the electric mechanism, in the present embodiment, the object driven by the utility model is a rotatable shift lever 50 located under the follower column 40, so only a pin head 61 of the pin 60 is required to be installed. In the chute 55 of driving rod 50, it is not necessary to set two pin heads. When the pin 60 is linearly displaced, the pin head 61 acts on the chute 55 to push the driving lever 50 to rotate. The diameter of the bolt tail 62 is larger than the diameter of the bolt head 61 , and it adopts an interference fit with the bolt hole 41 , so knurling is provided on the outer circle of the bolt tail 62 . When the motor 10 drives the cylindrical spring 20 to rotate, the pin 60 is limited by the chute 55 and cannot rotate with the cylindrical spring 20, but can only be displaced along the axial direction of the cylindrical spring 20 (see FIGS. 6 and 7 ).

Fig. 3 shows the structure of the cylindrical spring 20, as can be seen from Fig. 3, the cylindrical spring 20 includes a section of screw-in part 25 with a larger pitch that can be screwed into the pin 60 and a section of buffer part 26 with a pitch close to zero , the screw-in portion is about 15-17 turns, the pitch is 1.1-1.3 times the diameter of the pin 60, and the section of the buffer portion 26 is tightly wound for 7-9 turns. The role of the tightly wound section is to buffer the thrust of the pin 60 on the screw-in portion 25 , which will stretch the screw-in portion 25 . After the section of the tightly wound buffer part 26 is set, the buffer part 26 is also stretched when the screw-in part 25 is subjected to a stretching force, which is equivalent to increasing the number of stretched spring coils. Under the same conditions, the tensile force of each coil of the spring decreases, thus reducing the tensile force of the screw-in portion 25, and reducing the tensile force of the screw-in portion 25 means that the cylindrical spring 20 and the pin 60 The frictional force is reduced, so that the wear of the cylindrical spring 20 and the pin 60 can be reduced.

FIG. 4 , FIG. 5 and FIG. 6 respectively show the structures of the transmission shaft 30 and the follower shaft 40 . The drive shaft 30 includes a first shoulder 34 close to the motor 10 , a second shoulder 37 adjacent to the first shoulder 34 , a journal 33 adjacent to the second shoulder 37 , and an annular ring adjacent to the journal 33 . The convex strip 31 and the shaft extension 36 adjacent to the annular convex strip 31 . The first fixed ring 21 of the cylindrical spring 20 is sleeved on the journal 33, the first U-shaped bend 23 is clamped on the head portion 32 of the protruding line, and the tightly wound buffer portion 26 has several turns sleeved on the shaft extension. The pin hole 41 is located at the end of the follower column 40 close to the motor 10 . After the follower shaft 40 is loaded into the cylindrical spring 20 , the pin hole 41 is located at the center of the screw-in portion 25 .

7 and 8, it can be seen that the length of the follower shaft 40 is greater than the length of the cylindrical spring 20. When the follower shaft 40 is in the slide-in position, it extends to the buffer portion 26. When the follower shaft 40 is at When sliding out of the position, half of the screw-in part 25 is still sleeved on the follower post 40, so that during the rotation of the cylindrical spring 20 and the axial displacement of the follower shaft 40, the follower shaft 40 has maintained a certain alignment with the cylindrical spring 20. radial constraints. The diameter of the follower shaft 40 is slightly smaller than the diameter of the inner circle of the cylindrical spring, and the unilateral gap between them does not affect the axial sliding fit between them, and can limit the deviation generated when the cylindrical spring rotates to a small value. Appropriate degree. In this embodiment, the unilateral gap ranges from 0.15 mm to 0.30 mm.

The end of the follower shaft 40 slidingly fitted with the locking device is provided with two symmetrically protruding elliptical columns 42, and the slide rail matched with the two elliptical columns 42 is formed by an upper slide rail 75 arranged on the panel 1 (see Fig. 7 ) and the lower rail (not shown) on the bottom plate, the upper rail 75 is provided with two sections of depressions that just accommodate the elliptical column 42 on two parallel rectangular strips, and the lower rail is a protrusion opposite to the two sections of depressions After the panel 1 and the bottom plate are assembled, the elliptical column 42 is located between the upper slide rail 75 and the lower rail, and there is a gap between the elliptical column 42 and the slide rail that can maintain a sliding fit. The transmission shaft 30 and the follower shaft 40 can be made of metal materials, or other synthetic materials. In this embodiment, nylon material is used, and the follower shaft 40 adopts a hollow structure in order to reduce weight.

Fig. 7 and Fig. 8 have shown the embodiment that the utility model is applied to a kind of panel device of locking mechanical button, and this panel device comprises a panel 1 that is contained on the case cover, a bottom plate that matches with panel 1 (not shown in the figure Shown), a button 2 is arranged on the panel 1, and the lever 50 is arranged below the stroke of the button 2 to control whether the button 2 can be pressed. The electric mechanism of the utility model is arranged on one side of the button 2. The driving lever 50 includes a hub 51, on which a pivot 53 is arranged, and a pivot hole (not shown in the figure) matched with the pivot is arranged between the panel 1 and the bottom plate, and the driving lever 50 can rotate around the pivot hole , the arm 54 extends from the hub 51, the arm 54 is provided with a sliding groove 55 that can be loaded into the pin head 61, and the hub 51 is provided with three first teeth 56 and three adjacent first slots 57, A first protrusion 17 that can enter the first groove 57 is provided on the inner plane of the button 2 . When the driving lever is at the first angle, the three first teeth 56 are opposite to the three first protrusions 17. At this time, the downward stroke of the button 2 is blocked by the first teeth 56 of the driving lever 50 and cannot be pressed; When the rod 50 is pushed to the second angle by the pin head 61, the first groove 57 is opposite to the first protrusion 17, and the downward stroke of the button 2 is not blocked, and the first protrusion 17 is just when the button 2 is pressed. into the first slot 57 . Because there is a longer force arm between the pin 60 and the pivot 53 , the pin 60 can push the shift lever 50 to rotate with a small force, so as to realize locking and unlocking of the button 2 . A first position switch 71 is also set on the panel 1, and the end of the arm 54 can touch the first position switch 71 at a preset angle, and the position of the driving lever 50 is transmitted to the control unit of the locking device.

As shown in FIG. 7 , it is in the locked position at this time, the screw-in part 25 and the buffer part 26 of the cylindrical spring are simultaneously stretched to a certain extent, and the first tooth 56 on the driving rod 50 is against the first protrusion 17 on the button 2 , to prevent the button 2 from being pressed (in Figures 6 and 7, the direction in which the button 2 is pressed is the direction coming out of the paper), and after obtaining the authorization to unlock, the motor 10 drives the cylindrical spring 20 to rotate, and the follower shaft 40 is driven by the column The thrust generated by screwing the pin 60 into the cylindrical spring 20 slides axially from the locked position to the unlocked position, the pin 60 acts on the chute 55 to push the driving rod 50 to rotate through an angle, and the first tooth 56 of the driving rod 50 disengages from the second gear. One protrusion 17 offsets, and the first groove 57 turns to the position opposite to the first protrusion 17. During this process, the pin 60 is displaced to the left side of the cylindrical spring 20 circle by circle, and the tensile force is gradually reduced. Simultaneously, arm 54 ends have touched first position switch 71 (as shown in Figure 8), now press button 2, because there is no blocking, just can open case lock after button 2 is pressed. After the external force for pressing the button 2 is cancelled, the return spring (not shown in the figure) resets the button 2 . After the button 2 is reset, if the control unit of the locking device sends a locking signal, the motor 10 reverses, and the cylindrical spring 20 starts to move to the left side of the column pin 60 circle by circle, and the tensile force gradually increases until the column pin 60 Push the lever 3 back to the locked position until the blocking of the button 2 is resumed.

In Fig. 1 and Fig. 2, the structure of the fixed frame 65 can be seen. In order to prevent the transmission shaft 30 from axially displacing or disengaging from the motor shaft, causing operation failure, a fixed frame 65 is arranged between the rotating shaft 30 and the motor 10. The fixing frame 65 is bent with a slightly thicker steel wire, and the third U-shaped bend 66 perpendicular to the transmission shaft 30 has a diameter smaller than the first shoulder 34 and greater than the second shoulder 37, and it is placed inside the second shoulder 37 , the two symmetrical free ends 67 of the third U-shaped bend 66 are at right angles to the third U-shaped bend 66, forming a pair of fixed rods 67 pressed under the shell of the motor 10, when the motor 10 is fixed by the panel 1 and the bottom plate, The fixing bracket 65 is fixed thereupon. Under normal circumstances, the third U-shaped bend 66 does not contact any other part of the second shaft shoulder 37 and the transmission shaft 40. contact, preventing the transmission shaft 30 from continuing to displace axially. For the sake of reliability, a pair of L-shaped protrusions 77 are provided to block the inner side of the third U-shaped bend 66 at the position corresponding to the journal 33 on the panel 1. When the fixed frame 65 is pushed inward, the L-shaped protrusions 77 It can play the role of supporting the fixing frame 65 .

The above-mentioned embodiment is the preferred embodiment of the utility model, besides, the utility model can also be realized in other ways, under the premise of not departing from the technical scheme of the utility model, any other obvious replacements are all protected by the utility model within range.

Claims (10)

1. a kind of motor drive mechanism for locking device, including：One motor, a power transmission shaft for setting on the motor, one It is arranged at the helical spring of power transmission shaft, it is characterised in that：Also include：One axially displaced in helical spring can be servo-actuated Axle, one be located on servo axis can precession helical spring pin, the servo axis put in helical spring with the spiral bullet Spring is slidably matched.

2. the motor drive mechanism for locking device according to claim 1, it is characterised in that：The helical spring is cylinder Spring, the cylindrical spring includes precession portion and buffer part, pin axial displacement in the range of precession portion.

3. the motor drive mechanism for locking device according to claim 2, it is characterised in that：The pitch of the buffer part is Zero, the pitch in the precession portion is more than pin diameter.

4. the motor drive mechanism for locking device according to claim 3, it is characterised in that：The servo axis external diameter and institute The unilateral gap of cylindrical spring internal diameter is stated for 0.15mm-0.30mm, the pitch in the precession portion is the 1.1-1.3 of pin diameter Times.

5. the motor drive mechanism for locking device according to claim 2, it is characterised in that：Two of the cylindrical spring Free end is respectively equipped with the first U-bend that the first retainer plate and the second retainer plate be connected with the first retainer plate and solid with second The second connected U-bend of fixed circle；The power transmission shaft is provided with ring rib, and ring rib includes what is matched with the first U-bend Raised line head, the first U-bend is sheathed on raised line head, and the first retainer plate is loaded on ring rib outside.

6. the motor drive mechanism for locking device according to claim 1, it is characterised in that：The end of the servo axis sets It is equipped with the cylindroid for protruding from servo axis outer round surface.

7. the motor drive mechanism for locking device according to claim 1, it is characterized in that：The power transmission shaft includes first axle Shoulder and second shaft shoulder, including the fixed mount between power transmission shaft and motor case, the fixed mount include being fixed on outside motor Two fix bars and the 3rd U-bend perpendicular to fix bar of shell bottom, the 3rd U-bend are located at first shaft shoulder and the Limiting the axial displacement of power transmission shaft between two shaft shoulders.

8. the motor drive mechanism for locking device according to claim 7, it is characterized in that：The fixed mount is with a steel Silk is bent into, and the 3rd U-bend diameter is less than first shaft shoulder and is more than second shaft shoulder.

9. the motor drive mechanism for locking device according to claim 1, it is characterised in that：The motor drive shaft is flat axle, The power transmission shaft includes the flat axis hole matched with flat axle.

10. the motor drive mechanism for locking device according to claim 1-9 any one, it is characterised in that：It is described with Moving axis includes column pin hole, and the pin includes the head and the tail for being fixed on column pin hole between helical spring two adjacent rings Portion.