RU130338U1 - DOOR LOCK - Google Patents

Abstract

1. A door lock controlled by a cam rotatably connected to a door lock, the cam having a first protrusion, the door lock comprising a housing having a receiving chamber; a hole in communication with the receiving chamber and a guide stand protruding into the receiving chamber; a sliding element located in the receiving chamber, made with the possibility of sliding to the side and sequentially formed by the head, body and shank, while the head corresponds to the position of the hole, the body has a guide slot limiting the position of the groove and the locking portion, and the guide slot is made with the possibility of penetration into it of the guide rack, limiting the position the groove extends vertically, penetrating transversely through the body and crossing the guide slot to form a transition in which the side wall is made on the sliding element and is located outside the limiting position of the groove, while the locking portion is made on the sliding element and is located below the limiting position of the groove, while the shank has a slope sloping downward from the head; a latch having an end attached to the head of the sliding element and the other end penetrating the opening of the housing; Assumption member having a restricting portion and a position adjoining portion, wherein the position limiting portion is situated in a limiting position of the groove and is movable vertically along the groove confining position, wherein, once the position limiting portion is lowered and reaches the transition

Description

The present utility model relates to locks, and more particularly, to a door lock with a bolt mounted in a common housing.

Locks are devices of vital importance to ensure the safety of the location and convenience in daily life. Due to the trend towards compact and lightweight locks, locks are becoming more versatile. The traditional door lock is distinguished by the separation of its on / off function and the latch function, as a result, the traditional door lock has not only an excess of parts and components, but is also cumbersome. For this reason, a traditional door lock not only implies high manufacturing and assembly costs, but also lags behind the level of aesthetic trends.

From this point of view, the inventions related to this issue solve the above problems by mitigating the disadvantages of a traditional door lock, such as a short service life and a short stroke. However, the inventor of this application has discovered that there is still room for improvement of a traditional door lock. In the traditional door lock, a connecting lever 72 is used, which pivots and controls the relative position between the adjacent block 721 and the pushing block 715, and thereby controls the locking and unlocking of the traditional door lock. However, the aforementioned design has a drawback - the link arm 72 is thin, and thus likely to be moved; as a result, when subjected to external shock or vibration, the door lock is probably not working properly because the pushing unit 715 is likely to separate from the adjacent unit 721.

The objective of this utility model is to create a door lock that is unlikely to work properly even when subjected to external shock or vibration.

In order to achieve the above and other objectives, the present utility model proposes a door lock controlled by a cam rotatably connected to a door lock, the cam having a first protrusion, the door lock comprising: a housing having a receiving chamber; an opening in communication with the receiving chamber and a guide post protruding into the receiving chamber; a sliding element located in the receiving chamber, sliding to the side and sequentially formed by the head, body and shank, the head corresponding to the position of the hole, the body has a guide slot that limits the position of the groove and the locking portion, and the guide slot is made with the possibility of penetration into it of the guide rack The position-limiting groove extends vertically, penetrating across the body and crossing the guide slot to form a transition in which the side wall complete on the slide member and is disposed outside of the groove confining position, wherein the stopper portion is formed at the slide member and located below the limiting position of the groove, wherein the shank has a sliding ramp, inclined downward from the head; the latch has an end attached to the head of the sliding element, and the other end penetrating into the opening of the housing; the position-limiting element has a position-limiting portion and an adjacent portion, wherein the position-limiting portion is located in the position-limiting groove and is arranged to move vertically along the position-limiting groove, while as soon as the position-limiting portion is lowered and reaches the transition, the position-limiting portion will stop the guide a rack in the guide slot from the passage of the transition, while the adjacent section is connected with the bounding dix portion and located below the restricting portion position; wherein the first resilient member is located between the side wall and the position restricting member and has two ends adjacent to the side wall and the position restricting member, respectively, to actuate the position restricting member to actuate the position restricting portion to move to the transition; a second elastic element connected to the housing and the sliding element for actuating the sliding element to be closer to the hole; and a drive member rotatably coupled to the housing and continuing to form a second protrusion.

Accordingly, even if the door lock according to the present utility model is subjected to external shock and vibration, the door lock according to the present utility model is unlikely to work incorrectly, not only because the first resilient element abuts directly against the position restricting element, but also because the element restricting the position moves vertically only along the groove limiting the position.

The designs and features of the present utility model are further illustrated using specific embodiments of the present utility model in conjunction with the accompanying drawings, in which:

Figure 1 is a perspective view of a door lock according to a preferred embodiment of the present utility model;

FIG. 2 is an exploded view of a door lock according to a preferred embodiment of the present utility model; FIG.

Figure 3 is a perspective view of a sliding member in a rear view according to a preferred embodiment of the present utility model;

4 is a front view of a door lock according to a preferred embodiment of the present utility model;

5 is a schematic cross-sectional view of a closed door lock according to a preferred embodiment of the present utility model;

6 is a schematic view of an open door lock according to a preferred embodiment of the present utility model;

7 is a schematic view of a door lock in the closed / open state according to a preferred embodiment of the present utility model;

Fig. 8 is a schematic view of a guide rack with recesses located on both sides according to a preferred embodiment of the present utility model;

Fig. 9 is a schematic view of an adjacent portion formed by a first plane and a second plane according to a preferred embodiment of the present utility model;

As shown in FIGS. 1 to 4, schematic views of a door lock are shown in operation according to the present utility model. As shown in the drawing, the door lock is controlled by a cam 16. The cam 16 is rotatably connected to the door lock. The cam 16 has a first protrusion 161. The door lock mainly comprises a housing 11, a sliding element 12, a latch 13, a position restricting element 14, a first elastic element 15, a second elastic element 17 and a drive element 18.

The housing 11 has a receiving chamber 111 and an opening 112. The hole 112 is in communication with the receiving chamber 111. The housing 11 has a guide post 113. The guide post 113 projects into the receiving chamber 111.

The sliding element 12, which is made to slide to the side, is located in the receiving chamber 111. The sliding element 12 is sequentially formed by the head 121, the body 122 and the shank 123. The head 121 corresponds to the position of the hole 112. The body 122 has a guide slot 124 that limits the position of the groove 125 and the locking portion 126. Through the guide slot 124, the guide post 113 penetrates in a guiding manner (not shown). The position-limiting groove 125 extends vertically, penetrates laterally through the body 122 and intersects the guide slot 124 to form a transition 127. The side wall 128 is formed on the sliding element 12 and is located outside of the position-limiting groove 125. The locking portion 126 is formed on the sliding element 12 and is located below the limiting position of the groove 125. The shank 123 has a slope 129 slip, which is beveled down from the head 121.

The latch 13 has one end attached to the head 121 of the sliding element 12, and the other end penetrating the hole 112 of the housing 11.

The position-limiting element 14 has a position-limiting portion 141 and an adjacent portion 142. The position-limiting portion 141 is located in the position-limiting groove 125 and is arranged to move vertically along the position-limiting groove 125. As soon as the position-limiting portion 141 is lowered and reaches the transition 127, the limiting position section 141 will stop the guide rack 113 in the guide slot 124 from passing through the transition 127. The adjacent section 142 is connected to the bounding position 141 and is located below the limiting position 141. The adjacent section 142 is a flat or curved surface. In this preferred embodiment of the present utility model, the adjacent portion 142 is shown as an example in the form of a plane.

The first resilient member 15 is located between the side wall 128 of the body 122 and the position restricting member 14. The two ends of the first resilient member 15 are adjacent to the side wall 128 and the position restricting member 14, respectively, to actuate the position restricting member 14 to actuate the restricting position section 141 to move in the direction of transition 127. In this preferred embodiment of the present utility model, a mounting hole 143 corresponding to the first position the elastic element 15 is made in the position restricting element 14. The first elastic element 15 is inserted into the mounting hole 143 and is adjacent to the position restricting element 14. Therefore, the mounting hole 143 limits the range of motion of the first elastic element 15, thus allowing the first elastic element 15 to move smoothly.

The second elastic member 17 is connected to the housing 11 and the sliding member 12 to actuate the sliding member 12 to approach the hole 112.

The drive element 18 is rotatably connected to the housing 11. The drive element 18 continues to form a second protrusion 181.

In this preferred embodiment of the present utility model, the door lock further comprises a third elastic member 19 with two ends connected to the drive member 18 and the housing 11, respectively, to actuate the second protrusion 181 of the drive member 18 to rotate in the direction away from the sliding ramp 129 a shank 123. In a preferred embodiment of the present utility model, the door lock further comprises an adjustment bolt 21 for adjusting the push force applied by the third m of the elastic element 19 to the drive element 18. The adjusting bolt 21 is rotatably connected to the housing 11 and protrudes into the receiving chamber 111. The adjustable sliding mounting stand 22 is screwed to the adjusting bolt 21 and is driven by the adjusting bolt 21 to move inside the receiving chamber 111 either in the direction of the drive element 18, or in the direction from the drive element 18. In the aforementioned situation, the two ends of the third elastic element 19 are connected to the drive element 18 and an adjustable sliding Fastening rack 22, respectively, and thus the third elastic element 19 is connected to the housing 11 by the adjusting bolt 21.

In order to amplify the push applied by the third elastic member 19 to the drive member 18, the user must turn the adjusting bolt 21 to actuate the adjustable sliding fastening stand 22 to move away from the drive member 18. Therefore, if the user wants to rotate the drive member 18 to a predetermined position before adjustment, the user must apply a pre-adjustment force greater than the force before adjustment in order to rotate the drive element 18 to a predetermined position because the third elastic member 19 moves away from the drive member 18 after adjustment.

The design of the door lock according to the present utility model is described above. The operation of the door lock according to the present utility model is described below.

A. The door lock is closed.

As shown in FIGS. 4 and 5, the user applies a force under which the cam 16 rotates in the direction of the latch 13; meanwhile, the first protrusion 161 of the cam 16 comes into contact with the adjacent portion 142 of the position-limiting element 14, so that the position-limiting portion 141 slides upward. As a result, the position restricting portion 141 moves upward from the transition 127 and along the position limiting groove 125. After the position restricting portion 141 of the position restricting member 14 moves from the transition 127, the second elastic member 17 drives the sliding member 12 to move in the direction holes 112, so that the sliding element approaches the hole 112, thereby thereby causing the latch 13 to protrude from the housing 11; meanwhile, the guide post 113 passes the transition 127. After this, the first protrusion 161 of the cam 16 gradually moves away from the adjacent portion 142, and thus the position limiting element 14 is constantly pressed against the first elastic element 15, while moving downward. Ultimately, the position-restricting portion 141 returns to transition 127. After performing the aforementioned workflow, the position-limiting portion 141 of the position-limiting element 14 stops the guide post 113 in the guide slot 124 from passing through the transition 127, and thus the door lock according to the present utility model reaches its locking function.

B. Door lock in open mode.

As shown in FIG. 6, in order to open the door lock according to the present utility model, the user rotates the cam 16 away from the latch 13; meanwhile, the first protrusion 161 of the cam 16 comes into contact with the adjacent portion 142 of the position-limiting element 14, so that the position-limiting portion 141 slides upward. As a result, the position-limiting portion 141 moves upward from the transition 127 and along the position-limiting groove 125. After the position-limiting portion 141 of the position-limiting member 14 moves from the transition 127, the first protrusion 161 comes into contact with the locking portion 126 and thereby causes the action of the sliding element 12 to move away from the hole 112, thereby causing the latch 13 to be pulled into the housing 11; meanwhile, the guide post 113 passes the transition 127. After this, the first protrusion 161 of the cam 16 gradually moves away from the adjacent portion 142, and thus the position limiting element 14 is constantly pressed against the first elastic element 15, while moving downward. Ultimately, the position restricting portion 141 returns to the transition 127. At this point in time, the position restricting portion 141 of the position restricting member 14 stops the guide post 113 in the guide slot 124 from passing through the transition 127, and thus the sliding member 12 is driven by the drive member 18 to thereby allow the door lock to be in the open state.

C. Door lock in closed / open state.

As shown in FIG. 7, in order to start the operation of the door lock according to the present utility model in such a way as to achieve its closing / opening function, the user must make sure that the door lock is first in the open state. Since the second elastic element 17 drives the sliding element 12 to constantly move in the direction of the hole 112, the sliding element 12 approaches the hole 112 and causes the latch 13 to protrude from the housing 11; therefore, the latch 13 can limit the relative positions of the door panel and the door frame of the door lock, thereby performing its closing function. In order to open the door lock, the user must exert a force to rotate the drive element 18, thereby causing the second protrusion 181 of the drive element 18 to move in the direction of the shank 123 of the sliding element 12. After this, the second protrusion 181 comes into contact with the slide 129. With a constant rotation of the drive element 18, the second protrusion 181 slides relative to the slide 129 and away from the hole 112. Ultimately, the sliding element 12 and the latch 13 move away from the hole 112, thereby achieving the opening function.

As indicated above, even if the door lock according to the present utility model is subjected to external shock or vibration, the door lock according to the present utility model is unlikely to work incorrectly, not only because the first resilient member 15 is directly adjacent to the position restricting member 14, but also because the position-limiting element 14 moves vertically only along the position-limiting groove 125.

As shown in FIG. 8, as indicated in the above description of closing / opening the door lock, during the working process of closing / opening the door lock according to the present utility model, it is always possible for the position-limiting portion 141 of the position-limiting element 14 to come into contact with the guide 113. Therefore, in order to prevent the stop restricting the position of the portion 141 by the edge of the guide post 113 and to ensure smooth operation of the limiting position of the portion 141, it is necessary that on both sides of the guide post 113 were two recesses 114.

As shown in FIG. 9, since the first protrusion 161 of the cam 16 comes into contact with the adjacent portion 142 of the position restricting member 14, the position restricting portion 141 moves upward. After this, the first protrusion 161 of the cam 16 gradually moves away from the adjacent portion 142, and thus the position-limiting element 14 is constantly pressed against the first elastic element 15, while moving downward. Therefore, in this preferred embodiment of the present utility model, the abutting portion 142 is formed by the first plane 142a and the second plane 142b, with the second plane 142b being closer to the shank 123 of the sliding member 12 than the first plane 142a. The second plane 142b is beveled upward toward the shank 123, so that the first protrusion 161 can be separated from the adjacent portion 142 quickly enough to allow the position limiting element 13 to move downward.

Claims (7)

1. A door lock controlled by a cam rotatably connected to a door lock, the cam having a first protrusion, the door lock comprising a housing having a receiving chamber; an opening in communication with the receiving chamber and a guide post protruding into the receiving chamber; a sliding element located in the receiving chamber, made with the possibility of sliding to the side and sequentially formed by the head, body and shank, while the head corresponds to the position of the hole, the body has a guide slot, limiting the position of the groove and the locking portion, and the guide slot is made with the possibility of penetration into it of the guide rack, the groove limiting the position continues vertically, penetrating across the body and crossing the guide slot with the formation of a transition and wherein the side wall is formed on the slide member and is disposed outside of the groove confining position, wherein the stopper portion is formed at the slide member and located below the limiting position of the groove, wherein the shank has a sliding ramp, inclined downward from the head; a latch having an end attached to the head of the sliding element and the other end penetrating into the opening of the housing; a position-limiting element having a position-limiting portion and an adjacent portion, wherein the position-limiting portion is located in the position-limiting groove and is arranged to move vertically along the position-limiting groove, wherein as soon as the position-limiting portion is lowered and reaches the transition, the position-limiting portion will be stop the guide rack in the guide slot from passing the transition, while the adjacent section is connected to the bounding the position of the site and is located below the area that limits the position; a first resilient member located between the side wall and the position restricting member and having two ends adjacent to the side wall and the position restricting member, respectively, for actuating the position restricting member and the position restricting portion to move to the transition; a second elastic element connected to the housing and the sliding element for actuating the sliding element to be closer to the hole; and a drive member rotatably coupled to the housing and continuing to form a second protrusion. 2. The door lock according to claim 1, in which the adjacent section has a flat or curved surface. 3. The door lock according to claim 1, in which the installation hole corresponding in position to the first elastic element is made in the position-limiting element, wherein the first elastic element is placed in the installation hole to abut against the position-limiting element. 4. The door lock according to claim 1, additionally containing a third elastic element, which has two ends connected to the drive element and the housing, respectively, for bringing the second protrusion of the drive element into rotation in the direction from the slope of the shank. 5. The door lock according to claim 4, further comprising an adjusting bolt rotatably connected to the housing and protruding into the receiving chamber; an adjustable sliding fastening screw screwed to the adjustment bolt and driven by the adjustment bolt to move inside the receiving chamber, either in the direction of the drive element or in the direction from the drive element; the third elastic element having two ends connected to the drive element and adjustable sliding fastening rack, respectively, and connected to the housing using an adjusting bolt. 6. The door lock according to claim 1, in which two recesses are located on both sides of the guide rack. 7. The door lock according to claim 1, in which the adjacent section is formed by the first plane and the second plane, the second plane being closer to the shank of the sliding element than the first plane, the second plane inclined upward in the direction of the shank.

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