KR20210017562A - Speed gate driving apparatus - Google Patents

Abstract

The present invention relates to a speed gate driving device, which enables a center of gravity of a link unit rotated by a drive motor to be positioned at a center of rotational shafts to prevent torque from being generated by the load of the link unit when a door of a speed gate is opened and closed to enable the gate to smoothly perform opening and closing operation.

Description

Speed gate driving apparatus

The present invention relates to a speed gate driving device, and in particular, by ensuring that the center of gravity of the link portion rotated by the driving motor is located in the middle of the rotation shafts, torque is generated by the load of the link portion when the door of the speed gate is opened and closed. It relates to a speed gate driving device that prevents the opening and closing of the gate to be smoothly performed.

In general, a speed gate that is temporarily opened is installed in a passage requiring access control when an identity is confirmed while the gate is closed.

However, the conventional speed gate is started with a configuration in which a link member connected to the door plate is rotated by adding a belt and a pulley in addition to a driving motor to rotate the door plate, so that the structure is complicated, making it cumbersome and manufacturing cost increases. there is a problem.

In order to solve this problem, Korean Patent Registration No. 10-1612439 (name of invention: automatic gate for ticket gates) (hereinafter referred to as “conventional technology”) was developed.

1 is a perspective view of the prior art.

The conventional speed gate driving apparatus 100 includes a door plate 110, a frame unit 120, a driving unit 130, and a link unit 140.

The door plate 110 is fixed to the link unit 140 through a binding tool 111 provided at the side.

The frame unit 120 includes a front frame 121, a rear frame 122, and a base frame 123.

The front frame 121 and the rear frame 122 are made of rectangular metal plates having the same size, are arranged in parallel with each other, but are arranged so that the plate surface faces the passage direction, and the base frame 123 is fixed to the bottom of the passageway. Is fixed to

The driving unit 130 is a configuration in which the door plate 110 fixed to the link unit 140 swings, and the upper rotation shaft 131 is disposed vertically to penetrate the front frame 121 and the rear frame 122 It consists of a lower rotation shaft 132, a drive motor 133 and a speed reducer 134, which are coupled between the lower rotation shaft 132 and the shaft.

The link unit 140 swings the door plate 112 with the rotational force transmitted through the driving unit 130 but rotates while maintaining a set posture, and is disposed on the front frame 121 to rotate the upper rotation shaft 131 ) And the lower rotation shaft 132 are disposed on the upper driving arm 141 and the lower driving arm 142, and the rear frame 122, each of which has one end fixed to the upper rotation shaft 131 and the lower rotation shaft 132, respectively. In the fixed state, the other end is hinged to the fastening hole 111 of the door plate 110, the upper driven arm 143 and the lower driven arm 144, and both ends of the upper driving arm 141 and the lower driving arm 142 It consists of a connection arm 145 rotatably fixed to the other end of the.

The upper driving arm 141 and the lower driving arm 142 are made of link members having the same link length, and fastening holes for fixing the upper and lower rotating shafts 131 and 132 at the same point at both ends in the longitudinal direction. And a hinge member to be fixed to the connection arm 145, respectively.

In the speed gate driving device 100 configured as described above, the driving arms 141 and 142 have the same inclination angle with respect to the bottom surface, and the connecting arm 145 is at the same length point from the rotation shafts 131 and 132. In the hinged state, the driven arms 143, 144 also have the same inclination angle with respect to the floor surface, and the binding tool 111 is hinged at the same length point from the rotation shafts 131 and 132, thereby driving When the motor 133 is rotated, the door plater 110 swings while maintaining the set posture.

However, in this speed gate driving device 100, since the center of gravity of the link unit 140 is not located on the line connecting the rotation shafts 131 and 132, when the door plate 110 is opened and closed, the link unit 140 Torque is generated by the load and additional rotational force is applied to the rotational shafts, and as a result, moments are unevenly generated on the rotational shafts, and the opening and closing speed of the door plate 110 becomes uneven, so that the opening and closing operation cannot be performed smoothly.

The present invention is to solve this problem, and the problem of the present invention is to ensure that the center of gravity of the link portion having a parallelogram hinge coupling structure is located at the center of the rotating shafts, so that the torque due to the load of the link portion when the door of the speed gate is opened and closed It relates to a speed gate driving device that prevents the occurrence of the door so that the opening and closing operation of the door can be made smoothly.

In the speed gate driving device for driving the door plate in the speed gate installed on both sides of the passage to open and close the passage by operating the door plate, the solution means of the present invention for solving the above problem is formed in a plate shape and is parallel to each other. A frame portion having a front frame and a rear frame arranged to be arranged; An upper rotation module having both ends coupled to the front frame and the rear frame and having a rotation shaft installed therein; A lower rotation module having both ends coupled to the front frame and the rear frame, having a rotation shaft installed therein, and installed at a lower side of the upper rotation module; A drive motor installed in the frame to have a motor shaft installed in parallel with the upper rotation module and the lower rotation module; A front link part connected to a rotation shaft of the upper rotation module protruding forward of the front frame and protrusions of a rotation shaft of the lower rotation module; A rotation shaft of the upper rotation module protruding to the rear of the rear frame and a rear link part connected to protrusions of the rotation shaft of the lower rotation module and to which the door plate is coupled, and the front link part protrudes forward of the front frame. A motor arm installed on the protrusion of the motor shaft of the driving motor to rotate together with the motor shaft; A lower driving arm coupled with a protrusion of a rotation shaft of the lower rotation module having a center in the longitudinal direction protruding forward of the front frame; An upper driving arm coupled with a protrusion of a rotation shaft of the upper rotation module having a center in the longitudinal direction protruding forward of the front frame, and installed in parallel with the lower driving arm; A first connection link having a lower end hinged to one end of the motor arm, and an upper end hingedly coupled to one end of the lower driving arm; A second connection link whose lower end is hinged to one end of the lower driving arm, and the upper end is hingedly coupled to one end of the upper driving arm; The lower end is hinged to the other end of the lower driving arm, and the upper end includes a third connecting link hinged to the other end of the upper driving arm.

In addition, in the present invention, the rear link part includes a lower driven arm coupled with a protruding part of the rotation shaft of the lower rotation module at one end protruding to the rear of the rear frame; An upper driven arm coupled with a protrusion of a rotation shaft of the upper rotation module, one end protruding to the rear of the rear frame, and installed in parallel with the lower driven arm; It is preferable to include a door bracket hinged to the other end of the upper driven arm and the other end of the lower driven arm, and to which the door plate is coupled.

In addition, in the present invention, it is preferable that the front link portion and the rear link portion have bearings inserted into the hinge coupling portions, respectively.

In addition, in the present invention, it is preferable that the front frame includes a rotation limiting part that limits the rotation angle of the motor arm.

In addition, in the present invention, the front frame further includes spring holders protruding forward, and the upper driving arm includes an extension plate having a spring holder protruding forward above the rotation shaft of the upper rotation module, and the lower drive The arm includes an extension plate having a spring holder protruding forward from a lower portion of the rotation shaft of the lower rotation module, and the speed gate driving device has one end connected to spring holders formed on the upper rotation arm and the lower rotation arm, It is preferable that the other end further includes springs respectively connected to the spring holders formed in the front frame.

According to the present invention having the above problems and solutions, the front link part located in front of the frame part is coupled with the rotational shafts of the driving part at the center of the longitudinal direction of the driving arms, and both ends of the driving arms are hinged with the connecting links to form a parallelogram. By forming the hinge coupling structure, even if the driving arms are rotated by the rotation shafts, the center of gravity of the link part is located at the center of the rotation shafts, so that additional rotational force is prevented from being applied to the rotation shafts by the load of the front link part.

1 is a perspective view of the prior art.
2 is a perspective view of the speed gate driving apparatus of the present invention.
3 is a perspective view of the frame portion of FIG. 2.
4 is a side view of FIG. 2.
5 is an exploded perspective view of the rotation module of FIG. 4.
6 is a front view of FIG. 2.
7 is a rear view of FIG. 2.
8 is an exemplary view for explaining the opening and closing operation of the speed gate driving apparatus of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a perspective view of the speed gate driving apparatus of the present invention, and FIG. 3 is a perspective view of the frame portion of FIG. 2.

The speed gate driving device 1 includes a frame part 2, a driving part 3 installed inside the frame part 2, and a front link part 4 and a rear link part 5 connected to the driving part 3 And, it consists of a door plate (6) that is coupled to the rear link (5) and operated.

The frame portion 2 is composed of a front frame 21, a rear frame 22, and support frames 23a and 23b.

The front frame 21 and the rear frame 22 are made of a rectangular plate and are disposed parallel to each other, and the lower end is coupled to the support frames 23a and 23b. In addition, the front and rear frames 21 and 22 are installed perpendicular to the ground.

In addition, a rotation limiting unit 211 for limiting the rotation angle of the motor arm 41 of the front link unit 4 to be described later is installed under the front frame 21.

The rotation limiting unit 211 limits the rotation angle of the motor arm 41 to be described later so that the door plate 6 operates within a set angle.

In addition, spring holders 212a and 212b to which one end of the springs S to be described later are connected are formed to protrude forward on the front frame 21.

The support frames 23a and 23b consist of a horizontal portion 231 in contact with the ground and a vertical portion 232 coupled with the lower ends of the front and rear frames 21 and 22, and the front frame 21 ) And the rear frame (22).

4 is a side view of FIG. 2 and FIG. 5 is an exploded perspective view of the rotation module of FIG. 4.

The driving unit 3 is installed inside the front frame 21 and the rear frame 22, and consists of a driving motor 31, a lower rotation module 32a, and an upper rotation module 32b.

The drive motor 31 includes a motor shaft 311 that rotates as the drive motor 31 is operated, and the motor shaft 311 is combined with the motor arm 41 of the front link unit 4 to be described later to The rotational force is transmitted to the link unit 4.

The lower rotation module (32a) and the upper rotation module (32b) are installed in parallel with the drive motor (31), each of the hollow cylindrical module body (321a), (321b), the module body (321a), (321b) ) To the rotation shaft (322a), (322b) rotatably installed inside the module body (321a), (321b) and the bearing (323) installed between the rotation shaft (322a), (322b) Done.

Both ends of the module bodies 321a and 321b are bolted to the inner surfaces of the front and rear frames 21 and 22, respectively.

The rotation shafts 322a and 322b are formed in a rod shape, and insertion protrusions 3221a and 3221b inserted into the front link portion 4 and the rear link portion 5 are formed at both ends, respectively.

The driving unit 3 configured as described above transmits the rotational force to the front link unit 4 through the motor shaft 311 of the driving motor 31, and the front link unit is provided by the rotation modules 32a and 32b. By transmitting the rotational force of 4) to the rear link portion 5, the door plate 6 coupled with the rear link portion 5 is operated.

6 is a front view of FIG. 2.

The front link part 4 includes a motor arm 41 connected to the motor shaft 311 of the driving motor 31, a lower driving arm 42a connected to the rotation shafts 322a and 322b, and an upper drive. The arm 42b, the first connecting link 43 connecting the motor arm 41 and the lower driving arm 42a, and a first connecting link 43 connecting both ends of the lower driving arm 42a and the upper driving arm 42b, respectively. It consists of a 2 connecting link 44a and a third connecting link 44b.

In this case, for convenience of explanation, the second connection link 44a is installed on the left side, and the third connection link 44b is installed on the right side.

One end of the motor arm 41 is coupled to the motor shaft 311 of the drive motor 31 and rotates around the motor shaft 311 by receiving a rotational force from the drive motor 31.

In addition, the other end of the motor arm 41 is hinged with the first connection link 43.

Both ends of the first connecting link 43 are hinged to the other end of the motor arm 41 and the left end of the lower driving arm 42a, respectively, and transmit the rotational force of the motor arm 41 to the lower driving arm 42a. do.

The lower driving arm 42a and the upper driving arm 42b are formed in the shape of a square bar having the same length, and insertion grooves (not shown) are formed at the centers of the longitudinal direction, respectively.

At this time, the insertion grooves are formed in a shape corresponding to the insertion protrusion 3221a of the rotation shaft 322a.

These driving arms (42a) and (42b) are respectively inserted into the insertion grooves, the insertion protrusion (3221a) of the rotation shaft (322a) is inserted and coupled, so that when the driving arms (42a) and (42b) are rotated, the rotation shaft (322a) rotates together. do.

In addition, since the left end of the lower driving arm 42a is hinged with the first connecting link 43, when the motor arm 41 is rotated by the driving motor 31, the rotational force is applied through the first connecting link 43. It is transmitted and rotated based on the rotation shaft 322 of the lower rotation module 32a.

In addition, the left and right ends of the lower driving arm 42a are hinged to the lower ends of the second and third connecting links 44a and 44b, respectively.

The second connection link 44a and the third connection link 44b are formed in the shape of a square bar having the same length.

At this time, both ends of the second connecting link 44a are hinged to the left end of the lower driving arm 42a and the upper driving arm 42b, respectively, and both ends of the third connecting link 44b are respectively lower driving arms 42a. And it is hinged to the right end of the upper driving arm (42b).

These second and third connection links 44a and 44b transmit the rotational force of the lower driving arm 42a to the upper driving arm 42b.

These driving arms (42a), (42b) and the second and third connecting links (44a), (44b) form a parallelogram-type hinge coupling structure so that the lower driving arm (42a) and the upper driving arm (42b) are It has the same inclination angle as and when the lower driving arm 42a is rotated, the upper driving arm 42b is rotated by the same angle.

In addition, the driving arms 42a, 42b and the second and third connecting links 44a, 44b form a parallelogram hinged structure, so that the lower driving arm 42a and the upper driving arm 42b rotate. Even so, it has the same center of gravity.

In addition, bearings (not shown) are inserted into the hinged portions of the arms 41, 42a, and 42b and the connecting links 43, 44a, and 44b to prevent wear and noise.

Further, plate-shaped extension plates 422a and 422b are respectively installed on the lower driving arms 42a and the upper driving arms 42b.

The extension plates 422a and 422b are formed with spring holders 4221a and 4221b to which one end of the spring S is connected, respectively, to protrude forward.

The spring holders 4241a and 4221b fix both ends of the spring S together with the spring holders 212a and 212b formed on the first frame 21, respectively.

At this time, the spring (S) makes a moment opposite to the moment due to the self weight of the door plate 6 act on the rotation shaft 322, thereby canceling the moment due to the self weight of the door plate 6, thereby reducing the inertia resistance of the door plate 6 As a result, changes in the rotational speed of the door plate 6 are alleviated.

The front link part 4 configured as described above has a constant center of gravity by forming a parallelogram hinge coupling structure with the driving arms 42a and 42b and the second and third connecting links 44a and 44b. Therefore, the opening and closing operation of the door plate 6 is smoothly performed because rotational force due to the weight of the front link unit 4 is not generated during the opening or closing operation or in a stopped state.

In addition, the front link part 4 cancels the rotational force generated by the self weight of the door plate 6 through the springs S during the opening and closing operation of the door plate 6, thereby smoothing the opening and closing operation of the door plate 6 .

In addition, the front link portion 4 is worn by inserting bearings (not shown) into the hinged portions of the arms 41, 42a, and 42b and the connecting links 43, 44a, and 44b, respectively. And noise generation.

7 is a rear view of FIG. 2.

The rear link part 5 includes a lower driven arm 51 and an upper driven arm 52 coupled to the rotation shafts 322a and 322b of the rotation modules 32a and 32b, respectively, and the driven arm 51 It consists of a door bracket 53 that is hinged to the, 52 and fixes the door plate (6).

The lower driven arm 51 and the upper driven arm 52 are formed in the shape of a square rod having the same length, and insertion grooves 511 and 521 are formed at one end, respectively.

At this time, the driven arms 51, 52 are inserted into the insertion grooves 511, 521, the insertion protrusions 3221b of the rotation shafts 322a, 322b, respectively, and the rotation shafts 322a, 322b, and By being coupled, the rotation shafts 322a and 322b rotate together when they are rotated.

When the driving arms 42a and 42b are rotated by the driving motor 31, the rear link part 5 reduces the rotational force of the driving arms 42a and 42b through the rotation shafts 322a and 322b. The driven arms 51 and 52 are rotated by receiving the transmission.

8 is an exemplary view for explaining the opening and closing operation of the speed gate driving apparatus of the present invention.

FIG. 8A is a front view of the door plate 6 protruding and the passage is closed, and FIG. 8B is a front view of a state in which the passage is open.

As shown in (a) of FIG. 8, the speed gate driving device 1 maintains a state of closing the passage by protruding the door plate 6 to the outside of the body (not shown) in normal times, and opening the passage. If necessary, the drive motor 31 is operated so that the front link part 4, the rear link part 5, and the door plate 6 are rotated or moved in the direction shown in FIG. The passage is opened by entering the same state as (b).

Specifically, the speed gate driving device 1 rotates the driving motor 31 counterclockwise when the passage is opened, and the driving motor 31 and the motor arm 41 having one end coupled to the driving motor 31 Rotated counterclockwise by

At this time, since the other end of the motor arm 41 is hinged with one end of the first connection link 43, when the driving motor 31 is rotated counterclockwise, the first connection link 43 moves downward. do.

In addition, since the lower driving arm 42a is hinged with the first connecting link 43 while the center of the longitudinal direction is coupled to the rotation shaft 322a, it is rotated counterclockwise based on the rotation shaft 322a. It is rotated, and the lower driven arm 51 having one end coupled to the rotation shaft 322a is also rotated in a counterclockwise direction.

In addition, the second and third connecting links 44a and 44b are hinged to both ends of the lower driving arm 42a, so that the second connecting link 44a moves downward and the third connecting link 44b moves upward. do.

In addition, the upper driving arm 42b has a second connection because the left and right ends of the upper driving arm 42b are hinged with the second and third connecting links 44a and 44b while the center of the longitudinal direction is coupled to the rotation shaft 322b. As the link 44a moves downward and the third connection link 44b moves upward, it rotates counterclockwise with respect to the rotation shaft 322b.

At this time, the upper driven arm 52 is rotated counterclockwise together with the upper driving arm 42b because one end is coupled to the rotation shaft 322b.

Accordingly, the speed gate driving device 1 moves the door plate 6 hinged to the other end of the driven arms 51 and 52 to open the passage as shown in FIG. 8B. Is done.

1: speed gate driving device
2: frame part
21: front frame 22: rear frame
23a, 23b: support frame
3: drive unit
31: drive motor 32a: lower rotation module
32b: upper rotation module
4: front link part
41: motor arm 42a: lower driving arm
42b: upper driving arm 43: first connecting link
44a: second connection link 44b: third connection link
5: rear link part
51: lower follower arm 52: upper follower arm
53: door bracket 6: door plate

Claims (5)

In the speed gate driving device for driving the door plate in the speed gate installed on both sides of the passage to open and close the passage by operating the door plate:
A frame portion formed in a plate shape and having a front frame and a rear frame disposed in parallel with each other;
An upper rotation module having both ends coupled to the front frame and the rear frame and having a rotation shaft installed therein;
A lower rotation module having both ends coupled to the front frame and the rear frame, having a rotation shaft installed therein, and installed at a lower side of the upper rotation module;
A drive motor installed in the frame to have a motor shaft installed in parallel with the upper rotation module and the lower rotation module;
A front link part connected to a rotation shaft of the upper rotation module protruding forward of the front frame and protrusions of a rotation shaft of the lower rotation module;
A rotation shaft of the upper rotation module protruding to the rear of the rear frame and a rear link part connected to the projections of the rotation shaft of the lower rotation module and to which the door plate is coupled,
The front link part
A motor arm installed on a protrusion of a motor shaft of the drive motor protruding forward of the front frame and rotating together with the motor shaft;
A lower driving arm coupled with a protrusion of a rotation shaft of the lower rotation module having a center in the longitudinal direction protruding forward of the front frame;
An upper driving arm coupled with a protrusion of a rotation shaft of the upper rotation module having a center in the longitudinal direction protruding forward of the front frame, and installed in parallel with the lower driving arm;
A first connection link having a lower end hinged to one end of the motor arm, and an upper end hingedly coupled to one end of the lower driving arm;
A second connection link whose lower end is hinged to one end of the lower driving arm, and the upper end is hingedly coupled to one end of the upper driving arm;
And a third connection link, wherein a lower end is hinged to the other end of the lower driving arm, and an upper end is hingedly coupled to the other end of the upper driving arm. The method of claim 1, wherein the rear link unit
A lower driven arm coupled with a protrusion of a rotation shaft of the lower rotation module, whose one end protrudes to the rear of the rear frame;
An upper driven arm coupled with a protrusion of the rotation shaft of the upper rotation module, one end of which protrudes to the rear of the rear frame, and installed parallel to the lower driven arm;
And a door bracket hingedly coupled to the other end of the upper driven arm and the other end of the lower driven arm, and to which the door plate is coupled. The method of claim 2, wherein the front link portion and the rear link portion
A speed gate driving device, characterized in that bearings are inserted into each of the hinge coupling parts. The method of claim 3, wherein the front frame
And a rotation limiting unit for limiting a rotation angle of the motor arm. The method of claim 4, wherein the front frame
Further comprising spring holders protruding forward,
The upper driving arm is
Including an extension plate formed with a spring holder protruding forward above the rotation shaft of the upper rotation module,
The lower driving arm is
Including an extension plate formed to protrude forward a spring holder under the rotation shaft of the lower rotation module,
The speed gate driving device is
The speed gate driving apparatus further comprises springs having one end connected to the spring holders formed on the upper rotation arm and the lower rotation arm, and the other end connected to the spring holders formed on the front frame, respectively.

Images