KR102625164B1 - Slim type DeadBolt Structure of Digital Door Lock - Google Patents

Abstract

The present invention relates to a slim dead bolt driving structure for a digital door lock, comprising: a door lock housing 110; and a turn hub 120 installed on the door lock housing 110 and having a turn hub arm 122 formed on one side. ; and a dead bolt driving structure 130 that is slidably operated in conjunction with the rotational operation of the turn hub arm 122 so that one or more dead bolts 140 protrude or are accommodated outside the door lock housing 110. In the dead bolt driving structure of the digital door lock configured as follows,
The dead bolt driving structure 130 has a dead bolt driving groove 132 formed on the bottom surface into which the turn hub arm 122 is inserted and interlocked, and the dead bolt driving groove 132 is overlapped and projected on the upper surface. It relates to a slim dead bolt driving structure 100 of a digital door lock, characterized in that a dead bolt mounting portion 131 is formed at a position where the dead bolt is installed.

Description

Slim type DeadBolt Structure of Digital Door Lock}

The present invention relates to a slim dead bolt driving structure for a digital door lock, comprising: a door lock housing 110; and a turn hub 120 installed on the door lock housing 110 and having a turn hub arm 122 formed on one side. ; and a dead bolt driving structure 130 that is slidably operated in conjunction with the rotational operation of the turn hub arm 122 so that one or more dead bolts 140 protrude or are accommodated outside the door lock housing 110. In the dead bolt driving structure of the digital door lock configured as follows,

The dead bolt driving structure 130 has a dead bolt driving groove 132 formed on the bottom surface into which the turn hub arm 122 is inserted and interlocked, and the dead bolt driving groove 132 is overlapped and projected on the upper surface. It relates to a slim dead bolt driving structure 100 of a digital door lock, characterized in that a dead bolt mounting portion 131 is formed at a position where the dead bolt is installed.

Generally, a door lock device is installed on the entrance door of a place such as a house, apartment, or office to prevent unauthorized outsiders from entering. A locking device is installed in the door lock device to prevent the door from being opened arbitrarily from outside. The most common type is a mechanical door lock that manually locks and unlocks the door using a key.

However, these mechanical door locks have a problem of poor security due to their simple structure. In order to solve this problem, recently, solenoid-type door locks and motors that drive the dead bolt using an electromagnet and clutch and a motor that drives the dead bolt by a user authentication process such as password, fingerprint recognition, or card recognition have been developed. Driven door locks are mainly used. Among these, the motor-driven type, which has a simple structure and relatively low power consumption, is more preferred. Regarding the configuration and operation of such a motor-driven door lock, there are various prior inventions, including “Electric Mortise Locking Device Applied to Digital Door Lock (Korean Registered Utility Model No. 20-0360653)” in Prior Art Document 1 below.

Meanwhile, such motor-driven door locks are widely applied not only to doors made entirely of iron, but also to doors mainly made of glass. In this case, if the entire door is manufactured only with glass, problems may arise with the strength and durability of the door lock installation part, so in recent years, glass (1a) is inserted into the sash frame structure (1b) mainly made of metal, as shown in FIG. 1. Structural sash glass doors are widely used. In the case of a glass door with such a sash structure, in order to secure the necessary structural rigidity while maximizing the characteristics of the glass door such as permeability/openness, the sash structure is made of metal as much as possible and is manufactured as a frame structure with the minimum required width. It is desirable.

However, in the existing inventions, in order to operate the dead bolt to protrude or retract, as disclosed in the "Deadbolt Structure (Korean Patent Publication No. 10-2017-0120951)" of Prior Invention 2 below or as shown in FIG. It has a configuration that allows the turn hub arm 31 to operate within a connection groove 24 formed in the shape of an open groove on the dead bolt plate 20. The connection groove 24 is configured in an open form and is dead. The bolt had no choice but to be coupled to the dead bolt mounting portion 12 formed separately at a location that does not overlap the open connection groove 24.

Accordingly, since the width of the dead bolt plate required to secure a predetermined dead bolt operating distance had to be large, the overall width of the motor-driven door lock had to be accordingly large, as shown in FIG. 2. In this case, there was a problem in that recent glass doors with a reduced width of the metal frame were difficult or impossible to install.

Republic of Korea Registered Utility Model No. 20-0360653 Republic of Korea Patent Publication No. 10-2017-0120951

The present invention is a digital door lock that solves the problems of the existing inventions described above and is configured to overlap the dead bolt driving groove and the dead bolt mounting portion, thereby securing the same predetermined dead bolt operating range and narrowing the width. The task is to provide a slim deadbolt drive structure.

In addition, the task is to ensure that the dead bolt driving structure is supported and guided from above and below by the guide groove on the lower side and the guide rail on the upper side, so that it can not only drive smoothly but also more stably support the load applied to the dead bolt. do.

Meanwhile, the task is to provide a slim deadbolt drive structure for a digital door lock that can slimly reduce the width while using a drive motor with a standardized size.

In order to achieve the above-described problem, the slim dead bolt driving structure 100 of the digital door lock of the present invention includes a door lock housing 110, and is installed on the door lock housing 110, and has a turn hub arm 122 on one side. This is formed turn hub (120); and a dead bolt driving structure 130 that is slidably operated in conjunction with the rotational operation of the turn hub arm 122 so that one or more dead bolts 140 protrude or are accommodated outside the door lock housing 110. In the dead bolt driving structure of the digital door lock configured as follows, the dead bolt driving structure 130 has a dead bolt driving groove 132 formed on the bottom surface into which the turn hub arm 122 is inserted and interlocked, and the upper surface Characterized in that a dead bolt mounting portion 131 is formed at a position overlapping and projected onto the dead bolt driving groove 132.

Meanwhile, a guide groove 133 that is guided to the guide 111 formed in the door lock housing 110 is further formed on the bottom of the dead bolt driving structure 130, and the upper surface of the dead bolt driving structure 130 is formed. A guide rail 150 installed on the door lock housing 110 to guide and support; It is characterized in that it further includes.

In addition, a guide rail groove 151 formed on the guide rail 150; and a guide protrusion 134 formed on the upper surface of the dead bolt driving structure 130 so that it can be inserted into the guide rail groove 151; It is characterized in that it further includes.

In addition, the turn hub 120 further includes a turn hub gear 121, and a drive motor equipped with a drive motor gear 161 that links the turn hub gear 121 to an output shaft formed by being biased in one direction ( 160), the drive motor 160 is installed inside the door lock housing 110 so that the one direction in which the output shaft is biased is closer to the turn hub 120.

In addition, the structural center (SC) of the drive motor 160 is located at the reference center line (C).

According to the present invention, the deadbolt driving groove and the deadbolt mounting portion are configured to overlap, so that the width can be slimly reduced while securing the same predetermined deadbolt operating range, so that the width of the metal frame is reduced. It can be easily installed on small glass doors, so it has the advantage of wide application.

In addition, the dead bolt driving structure is supported and guided from above and below by the lower guide groove and the upper guide rail, so that it can drive smoothly and more stably support the load applied to the dead bolt.

On the other hand, while using a drive motor with a standardized size and a shape in which the output shaft is biased in one direction, the width can be slimmed down, which has the advantage of ensuring ease of manufacturing and lowering the manufacturing cost.

Figure 1: A photograph showing an example of a glass door to which the present invention is applied.
Figure 2: A photograph showing the internal structure and width of a digital door lock according to an existing invention.
Figure 3: A diagram showing the slim dead bolt driving structure of a digital door lock according to an embodiment of the present invention.
Figure 4: A perspective view showing a dead bolt driving structure of a slim dead bolt driving structure of a digital door lock according to an embodiment of the present invention.
Figure 5: An exploded perspective view of the main components of the slim dead bolt driving structure of a digital door lock according to an embodiment of the present invention.
Figure 6: A photograph showing the internal structure and reduced width of the slim deadbolt driving structure of a digital door lock according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, the slim dead bolt driving structure of a digital door lock according to an embodiment of the present invention will be described in detail. First of all, it should be noted that in the drawings, identical components or parts are indicated by the same reference numerals whenever possible. In describing the present invention, detailed descriptions of related known functions or configurations are omitted in order to not obscure the gist of the present invention.

As shown in FIG. 3, the slim dead bolt driving structure of the digital door lock of the present invention largely includes a door lock housing 110, a turn hub 120, a dead bolt driving body 130, and a dead bolt 140. .

The door lock housing 110 is configured to be mounted on the metal frame portion of the door, and has the function of a basic structure on which other components of the slim dead bolt driving structure of the digital door lock of the present invention are mounted and installed.

Next, the turn hub 120 will be described. The turn hub 120 is installed in the door lock housing 110 to rotate in conjunction with the operation of a manual operation knob (not shown) or a drive motor 160 to be described later for locking/opening the door lock. Meanwhile, as shown in FIG. 3, the turn hub 120 has a turn hub arm 122 formed on one side.

Next, the dead bolt driving structure 130 will be described. As shown in FIG. 3, the dead bolt driving structure 130 is linked to the rotational operation of the turn hub arm 122 so that one or more dead bolts 140 protrude or are stored outside the door lock housing 110. It is configured to operate in a sliding manner. In this case, the dead bolt 140 is assembled by being mounted on the dead bolt mounting portion 131 formed on the dead bolt driving structure 130. Since this configuration is widely known and practiced in the technical field to which the present invention belongs, as can be seen in popular patent documents, detailed description will be omitted.

Meanwhile, in order to slimly reduce the width, which is the main problem of the present invention, the turn hub arm 122 is inserted into the bottom of the dead bolt drive structure 130, as shown in FIGS. 3 and 4. A deadbolt driving groove 132 that interlocks with the deadbolt is formed, and the deadbolt mounting portion 131 is formed on the upper surface at a position that overlaps and projects the deadbolt driving groove 132.

In the existing invention, as can be seen in Patent Document 2 or FIG. 2, the deadbolt drive groove and the deadbolt mounting portion are not arranged in an overlapped projected position but are formed spaced apart from each other in the sliding direction, so the deadbolt drive structure in the sliding direction The width of the portion occupied by the deadbolt driving groove and the deadbolt mounting portion in the overall width of is always larger than the sum of the width of the deadbolt driving groove and the width of the deadbolt mounting portion.

In contrast, in the case of the present invention, due to the feature that the dead bolt mounting portion 131 is formed at a position partially or fully overlapped and projected onto the dead bolt driving groove 132, the dead bolt driving groove and the dead bolt mounting portion are occupied. The width of the part has the characteristic that it is always smaller than the sum of the width of the deadbolt driving groove and the width of the deadbolt mounting portion. Therefore, even when securing the same movement width of the dead bolt, it is possible to make the width of the dead bolt driving structure 130 slimmer than that of the existing invention.

On the other hand, in the case where the dead bolt mounting portion 131 is formed in a position partially or fully overlapped and projected to the dead bolt driving groove 132, the driving force of the turn hub arm 122 is transmitted. The deadbolt driving groove 132 and the deadbolt mounting portion 131 are inevitably formed to be spaced apart from each other in a direction perpendicular to the sliding direction. Therefore, despite these features, in order to smoothly transmit and operate the driving force, a guide groove 133 is provided on the bottom of the dead bolt driving structure 130, which is guided to the guide 111 formed on the door lock housing 110, as shown in FIG. 4. ) is further formed and further includes a guide rail 150 installed on the door lock housing 110 to guide and support the upper surface of the dead bolt driving structure 130, so that the dead bolt driving structure ( It is desirable to allow both the upper and lower surfaces of 130) to be guided and operated.

In this case, in order to support and guide more precisely, as shown in Figures 3 and 5, a guide rail groove 151 formed on the guide rail 150 and a guide rail groove 151 to be inserted into the guide rail groove 151 It is preferable that the dead bolt drive structure 130 further includes a guide protrusion 134 formed on the upper surface of the dead bolt drive structure 130.

These structural features enable smooth operation as well as more stable support of the load applied to the dead bolt.

Meanwhile, digital door locks are usually operated by a drive motor. Recently, the drive motor has been modularized in a form with integrated and built-in reduction gears, etc., as shown in FIG. 3, thereby improving convenience of manufacturing and ease of maintenance. There is a trend to encourage this. In order to minimize the size of this modular drive motor 160 while arranging the motor and reduction gear inside, the output shaft is inevitably formed with a bias in one direction as shown in FIG. 3. The morphological characteristic of the drive motor 160 formed by deflecting the output shaft in one direction is such that the driving force of the output shaft of the drive motor 160 is transmitted to the turn hub 120, which is usually installed on the reference center line (C). In order to satisfy the conditions, it inevitably acts as a constraint in reducing the width of the overall shape of the digital door lock.

Therefore, in order to reduce the width of the overall shape of the digital door lock as much as possible while using the drive motor 160, which has a shape characteristic in which the output shaft is deflected in one direction, the turn hub 120 includes a turn hub gear 121. It further includes and is driven by a drive motor 160 equipped with a drive motor gear 161 that links the turn hub gear 121 to an output shaft formed by being biased in one direction, and the drive motor 160 is shown in FIG. 3 As shown, it is preferable that the one direction in which the output shaft is biased is tilted closer to the turn hub 120 and installed inside the door lock housing 110.

In this case, in order for the drive motor 160 of a given size to be installed inside the door lock housing 110 while occupying the minimum width, the structural center SC of the drive motor 160 is as shown in FIG. Likewise, it is most desirable to be located at the reference center line (C).

The slim dead bolt driving structure 100 of the digital door lock of the present invention having such a configuration has a width of about 57 mm as shown in FIG. 6, which shows one embodiment, which means that the existing invention shown in FIG. 2 has a width of about 70 mm. It can be seen that there is an effect of reducing the width by about 20% compared to having a width of ㎜.

In the above, optimal embodiments have been disclosed in the drawings and specifications. Although specific terms are used here, they are used only for the purpose of describing the present invention and are not used to limit the meaning or scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the attached patent claims.

100: Slim dead bolt driving structure of digital door lock
110: Door lock housing
111: Guide
120: turn hub
121: turn hub gear 122: turn hub arm
130: Dead bolt driving structure 131: Dead bolt mounting portion
132: Deadbolt driving groove 133: Guide groove
134: Guide projection
140: dead bolt
150: Guide rail 151: Guide rail groove
160: drive motor
161: Drive motor gear

Claims (5)

Door lock housing (110);
A turn hub 120 installed in the door lock housing 110 and having a turn hub arm 122 formed on one side;
A dead bolt driving structure 130 that is slidably operated in conjunction with the rotation of the turn hub arm 122 so that one or more dead bolts 140 protrude or are stored outside the door lock housing 110. In the dead bolt driving structure of a digital door lock,
The dead bolt driving structure 130,
A deadbolt driving groove 132 is formed on the bottom surface into which the turn hub arm 122 is inserted and interlocked, and a deadbolt mounting portion 131 is formed on the upper surface at a position that overlaps and projects the deadbolt driving groove 132. A slim dead bolt driving structure (100) of a digital door lock, characterized in that it is formed.
The method of claim 1,
A guide groove 133 that is guided to the guide 111 formed in the door lock housing 110 is further formed on the bottom of the dead bolt driving structure 130,
A guide rail 150 installed on the door lock housing 110 to guide and support the upper surface of the dead bolt driving structure 130; A slim dead bolt driving structure (100) of a digital door lock, characterized in that it further comprises a.
The method of claim 2,
A guide rail groove 151 formed in the guide rail 150;
A guide protrusion 134 formed on the upper surface of the dead bolt driving structure 130 so as to be inserted into the guide rail groove 151; A slim dead bolt driving structure (100) of a digital door lock, characterized in that it further comprises a.
The method of claim 3,
The turn hub 120 further includes a turn hub gear 121, and a drive motor 160 equipped with a drive motor gear 161 that interlocks the turn hub gear 121 with an output shaft formed to be biased in one direction. It is driven by,
The drive motor 160 is tilted so that the one direction in which the output shaft is biased is closer to the turn hub 120, and is installed inside the door lock housing 110. A slim dead bolt drive structure of a digital door lock. (100). The method of claim 4,
Slim dead bolt drive structure 100 of a digital door lock, characterized in that the structural center (SC) of the drive motor 160 is located at the reference center line (C).