KR101601729B1 - Apparatus for testing durability of elevator door driving equipment - Google Patents

Abstract

The present invention relates to a durability testing apparatus for an elevator door driving apparatus capable of easily and easily confirming whether a durability of the elevator door driving apparatus is simple or not by automatically detecting whether the elevator door driving apparatus is operated normally by repeatedly operating belts and poly.
The main construction of the present invention is characterized in that the elevator door driving device 10 comprises a belt 11, a first poly 12 connected to one end of the belt, and a second poly 13 connected to the other end of the belt 11 A support shaft 210 fixed to the upper surface of one side of the base plate 110; a rotation shaft 220 inserted through the support shaft 210 and provided with the first poly 12; And a driving unit 230 for rotating the first poly 23 and the second poly 23 disposed on the upper surface of the base plate 110 of the case 100 so that the second poly 13 can be rotated And a guide unit 320 for moving the polychamber unit 310. The second polychrome unit 310 moves the second polychrome unit 310 of the second support member 300, A position fixing member 400 which tightly fixes the belt 11 connected to the position fixing member 400 and the second supporting member 300 and a position fixing member 400 which is provided between the position fixing member 400 and the second supporting member 300, A tensile force measuring unit 500 for measuring a tensile force pulling the fixing unit 310; A member to be detected 600 installed on the belt 11 of the elevator door driving device 10 and horizontally moving together when the belt 11 horizontally moves left and right, A first malfunction detection sensor 710 installed to detect a subject to be sensed 600 moving in one direction and a sensing member 600 installed to be spaced apart from one side of the second sensing member 300 and moving in the other direction And a count sensor 730 disposed between the first malfunction detection sensor 710 and the second malfunction detection sensor 720 for counting the number of times the belt is operated. The control unit 700 controls the driving unit 230 of the first supporting member 200 and detects the malfunction of the elevator door driving apparatus 10 when the first and second malfunction detection sensors 710 and 720 detect the first and second malfunction detection sensors 710 and 720, And a control member (800) for confirming whether or not the elevator door Durability test apparatus of the apparatus.

Description

TECHNICAL FIELD [0001] The present invention relates to a durability testing apparatus for an elevator door driving apparatus,

The present invention relates to a durability testing apparatus for an elevator door driving apparatus capable of easily and easily confirming whether a durability of the elevator door driving apparatus is simple or not by automatically detecting whether the elevator door driving apparatus is operated normally by repeatedly operating belts and poly.

Generally, a pair of poly and a pair of poly-aramide belts are wound in a driving device for opening and closing the elevator door. Here, the belt is connected to the door and moves in the horizontal direction together with the elevator door, and when one poly is rotated by the driving force of the electric motor, the belt is horizontally moved, and the other poly is also rotated so that the elevator door is displaced to open and close the door.

When the elevator door is repeatedly opened and closed a plurality of times, the load of the poly and the belt installed on the elevator door becomes large, and when the door is broken due to the durability problem, the repair cost is increased, Is lowered.

The belt and the poly of the elevator door driving apparatus described above are operated by the operator several times in the exposed space of the work site during the production process and then mounted on the elevator when it is judged that there is no abnormality. The belt of the device and the poly are required to determine the defect rate through various tests such as repetitive operation prior to shipment, and it is necessary to distribute good quality elevators through the spread of such test devices.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus for testing the durability of an elevator door driving apparatus capable of confirming the durability against the number of times of normal operation by repeatedly reciprocatingly rotating the belt and the poly of the elevator door driving apparatus.

In addition, another object of the present invention is to provide a durability of an elevator door driving device capable of easily measuring whether or not a normal operation is performed while simultaneously operating a plurality of poly and belts using one driving part, And a test apparatus.

According to another aspect of the present invention, there is provided an apparatus for testing the durability of an elevator door driving apparatus including a belt, a first poly connected to one end of the belt, a second poly connected to the other end of the belt, A supporting table 210 fixedly installed on an upper surface of one side of the base plate 110 and a supporting table 210 fixed to the upper surface of the base plate 110. The elevator door driving apparatus 10 comprises a case 13, A first supporting member 200 including a rotating shaft 220 on which the poly 12 is installed and a driving unit 230 rotating the rotating shaft and a second supporting member 200 on the upper surface of the other side of the base plate 110 of the case 100, A second supporting member 300 composed of a polypropylene fixing unit 310 for fixing the poly 13 to be rotatable and a guide unit 320 for moving the polypropylene fixing unit 310, A position fixing member 400 for tightly fixing the belt 11 connected to the second poly 13 by moving the poly fixing unit 310 of the first poly 13, A tensile force measuring unit 500 installed between the member 400 and the second supporting member 300 and measuring a tensile force pulling the polychorusment 310 from the position fixing member 400; A member to be detected 600 installed on the belt 11 of the elevator door driving device 10 and horizontally moving together when the belt 11 horizontally moves left and right, A first malfunction detection sensor 710 installed to detect a subject to be sensed 600 moving in one direction and a sensing member 600 installed to be spaced apart from one side of the second sensing member 300 and moving in the other direction And a count sensor 730 disposed between the first malfunction detection sensor 710 and the second malfunction detection sensor 720 for counting the number of times the belt is operated. The control unit 700 controls the driving unit 230 of the first supporting member 200 and detects the failure of the elevator door driving device 10 when the first and second malfunction detection sensors 710 and 720 detect the first and second malfunction detection sensors 710 and 720. [ And a control member (800) for identifying the elevator door drive Equipment durability test apparatus.

Preferably, a plate-shaped base plate 110 is provided under the case 100.

Preferably, the support table 210 is formed with a through hole 211 passing through both side surfaces thereof, and a bearing part 240 is provided between the through hole 211 and the rotation shaft 220 so as to be rotatable.

Preferably, the through hole 211 of the support 210 is open at the upper side and has an upper lid 212 for closing the opened portion and the upper lid 212 is fastened to the upper portion of the support 210 .

 The polychorusment unit 310 preferably includes a lower plate 311 horizontally installed on the upper surface of the other side of the base plate 110 and a lower plate 311 extending upwardly from the upper surface of the lower plate 311, A rotation pin 220 'formed of a plate 312 and formed with a through hole 313 at the rear surface of the side wall plate 312 and inserted and fixed to the through hole 313 and a through hole 313, And a bearing portion 240 is fixed between the pins 220 '.

 The guiding part 320 may include a guide block 321 formed on the rear surface of the lower plate 311 of the polychoron 310 and a guide rail 322 horizontally installed on the base plate 110 of the case 100 corresponding to the guide block 321. [ ).

Preferably, the position fixing member 400 includes an adjustment box 410 positioned on the outer side of the second support member 300 and connected to the second support member 300 while being spaced apart from the base plate 110, A fixing bracket 430 fixed to the base plate 110 at the outside of the box 410 and a fixing bracket 430 fixed at one end to the adjusting box 410 and the other end passing through the fixing bracket 430, And a male screw portion 420 horizontally moving in the direction of the fixing bracket 430. [

Preferably, the control box 410 is formed in a rectangular frame shape having an inner space and spaced apart from the polyhedral fastener 310 by a predetermined distance, a through hole 411 formed at one side thereof, and a screw hole (412) is formed.

The connection rod 440 is formed so that the adjustment box 410 and the polygonal part 310 of the second supporting member 300 can be connected to each other.

Preferably, the fixing bracket 430 is formed with a through hole 431 such that the male screw portion 420 passes through the through hole 431. The diameter of the through hole 431 is slightly larger than the diameter of the male screw portion 420, .

Preferably, the member to be sensed 600 is formed of an opaque material recognizable by the sensor member 700, and is formed in a thin plate shape having a light weight so as not to interfere with the tensile force of the belt 11.

The support brackets 701 for supporting the first and second malfunction detection sensors 710 and 720 and the count sensor 730 are installed below the sensor member 700 .

The control member 800 preferably includes a driving sub-operation portion 810 for controlling the operation of the driving portion 230 and a tension force confirming portion 810 for confirming the pulling force applied to the belt 11 by being connected to the tension measuring portion 500 A counter management section 830 for counting and controlling the number of times the belt 11 is operated while communicating with the count sensor 730 and the operation of the belt 11 in communication with the first and second malfunction detection sensors 710, A failure confirmation unit 840 for confirming the status of the system, and a display unit 850 for displaying the operating status of the system.

The durability testing apparatus of the elevator door driving apparatus of the present invention has the effect of confirming the durability against the number of times of normal operation by repeatedly reciprocatingly rotating the belt and the poly of the elevator door driving apparatus in parallel.

In addition, the present invention can easily grasp the operation state of a plurality of poly belts by operating one driving unit at the same time, thereby improving the working efficiency by shortening the test work time.

1 is an overall perspective view of an apparatus for testing durability of an elevator door driving apparatus according to an embodiment of the present invention;
2 is a partial perspective view of an apparatus for testing durability of an elevator door driving apparatus according to an embodiment of the present invention,
3 is a partially enlarged perspective view of an apparatus for testing durability of an elevator door driving apparatus according to an embodiment of the present invention,
4 is a front view of the durability testing apparatus of the elevator door driving apparatus according to the embodiment of the present invention,
5 is a configuration diagram of an apparatus for testing the durability of an elevator door driving apparatus according to an embodiment of the present invention,
6 is a block diagram of an apparatus for testing durability of an elevator door driving apparatus according to an embodiment of the present invention.

Hereinafter, an elevator door driving apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, an apparatus for testing the durability of an elevator door driving apparatus according to an embodiment of the present invention includes a case 100 having an internal space, a first supporting member 200, A member 300, a position fixing member 400, a tension measuring unit 500, a member to be detected 600, a sensor member 700, and a control member 800.

First, the elevator door driving apparatus 10 tested by the present invention is interlocked with the elevator door, and can open and close the elevator door while moving the elevator door in the width direction of the doorway. The elevator door driving apparatus 10 to be tested here comprises a belt 11 horizontally moving in the same direction together with the elevator door, a first poly 12 connected to one end of the belt 11 to rotate the belt 11, And a second poly (13) connected to the other end of the belt (11) while being spaced a predetermined distance from the first poly (12) and rotated by the circular movement of the belt (11). At this time, the to-be-sensed member 600 to be described later may be installed on the belt 11 so as to be sensed by the sensor member 700.

The case 100 includes a belt 11, a first poly 12 connected to one end of the belt, a second poly 12 extending from the other end of the belt 11, And a second poly (13) connected to the second poly (13). The case 100 may be made of a transparent acrylic material or tempered glass, which can be visually inspected inside without opening the door. At this time, a plate-shaped base plate 110 is provided under the case 100. The base plate 110 is horizontally installed in a plate shape to facilitate installation of the elevator door driving device 10 to be tested.

The first supporting member 200 is mounted on one side of the case 100 and is mounted on the upper surface of the base plate 110 of the case 100 for supporting the first poly 12, A rotation shaft 220 penetratingly coupled to the support 210 and provided with the first poly 12, and a driving unit 230 rotating the rotation shaft.

The support base 210 rotatably supports both ends of the rotation shaft 220. The supporting part 210 may have a through hole 211 passing through both side surfaces thereof and a bearing part 240 to be rotatable between the through hole 211 and the rotating shaft 220. An upper lid 212 is provided to open the upper portion of the through hole 211 and close the opened portion so that the rotary shaft 220 can be easily attached to and detached from the through hole 211, Is preferably fastened to the top of the support 210.

The rotation shaft 220 may be installed so that the first poly 12 is coupled to the rotation shaft 220 and rotatable about the rotation axis 220. The rotation shaft 220 is formed into a bar shape extending through the through hole 211 of the support 210 and extending in the axial direction.

The driving unit 230 may be connected to a rotating shaft to stop or rotate the rotating shaft 220. The driving unit 230 may be electrically connected to the control member 800 to control the operating state. That is, the rotation of the driving unit 230 can be operated at a low speed and at a high speed in a stepwise manner, and it is needless to say that the rotation direction of the driving unit 230 can be a forward rotation and a reverse rotation. At this time, the driving unit 230 is preferably a computer or a digitally controlled pulse motor.

The second support member 300 is disposed at a position corresponding to the first support member 200 and is disposed on the upper surface of the other side of the base plate 110 of the case 100 for mounting the second poly 13, 2, a poly-fixing unit 310 for fixing the poly-13 in a rotatable manner, and a guide unit 320 for moving the poly-fixing unit 310.

 The polychorusment unit 310 includes a lower plate 311 horizontally installed on the upper surface of the other side of the base plate 110 and a lower plate 311 extending upwardly from the upper surface of the lower plate 311, ). That is, the polychoruscent portion 310 has a shape corresponding to the first supporting member 100 and a shape with the front portion opened. The polychoruscent part 310 includes a rotation pin 220 'having a through hole 313 formed in the rear surface of the side wall plate 312 and inserted and fixed in the through hole 313 and a through hole 313, And the second poly 13 is coupled to the rotation pin 220 'so as to rotate around the rotation pin 220'.

 The guide part 320 is composed of a guide block 321 formed on the rear surface of the lower plate 311 of the polychoron 310 and a guide rail 322 provided horizontally on the base plate 110 of the case 100 corresponding to the guide block 321 have. In other words, the polychorusment unit 310 can be horizontally moved in the left-right direction at the upper portion of the guide rail 322.

The first poly 12 fixed to the first supporting member 200 and the second poly 13 fixed to the second supporting member 300 can be installed in a state where the belt 11 is horizontally connected have. This belt 11 is rotated equally by the rotation of the first poly 12 and the rotational force of the belt 11 is transmitted to the second poly 13 and can rotate.

The position fixing member 400 can move the poly fixing portion 310 of the second supporting member 300 to tighten the belt 11 connected to the second poly 13 of the elevator driving device to provide a tensile force have. The position fixing member 400 includes an adjustment box 410 positioned on the outer side of the second support member 300 and connected to the second support member 300 while being spaced apart from the base plate 110, A fixing bracket 430 fixed to the base plate 110 at an outer side of the fixing plate 410 and a fixing bracket 430 fixed at one end to the fixing box 410 and the other end passing through the fixing bracket 430, And a male screw portion 420 horizontally moving in the direction of the bracket 430.

The adjustment box 410 is formed in a rectangular frame shape having an inner space so as to be spaced apart from the polyhedral portion 310 by a predetermined distance. The adjustment box 410 may have a through hole 411 formed at one side thereof and a screw hole 412 formed at the other side thereof with a female thread. At this time, the connection rod 440 is formed so that the adjustment box 410 and the polygonal part 310 of the second supporting member 300 can be connected to each other. One end of the connecting rod 440 is fixedly installed on one side of the side wall plate 312 of the poly fixing unit 310 and the other end of the connecting rod 440 is inserted into the connecting hole 411 of the adjusting box 410 Can be fixedly installed.

The fixing bracket 430 is fixed to the upper surface of the base plate 110 while being spaced apart from the other side of the adjustment box 410, and is formed vertically. The through hole 431 is formed in the fixing bracket 430 such that the male screw portion 420 passes through the through hole 431. The diameter of the through hole 431 is slightly larger than the diameter of the male screw portion 420, Can be installed.

The male screw portion 420 is fixed to the fixing bracket 430 by fixing the male screw portion 420 on the outer circumferential surface of the male screw portion 420 so that one end thereof can be screwed into the screw hole of the adjustment box 410. [ The adjustment screw 410 can be moved in the axial direction of the male screw portion 420 by rotating the head portion of the male screw portion 420 when the male screw portion 420 is rotated. That is, as the adjustment box 410 is fastened to the male screw portion 420, the tensile force applied to the belt 11 can be increased.

The control box 410 of the position fixing member 400 and the polygonal portion 310 of the second supporting member 300 are installed in the thermostatic rod 440, A tensile force measuring unit 500 may be further installed to measure a tensile force to pull the pipe.

The tensile force measuring unit 500 is installed between the control box 410 of the position fixing member 400 and the polystyrene unit 410 of the second supporting member 300. The tensile force measuring unit 500 measures the tensile force pulling the polystyrene unit 410 by the adjustment box 410 and provides the tensile force to the control member 700 in an electrically connected state to the control member 700.

The member to be detected 600 is disposed on the lower side of the belt 11 to be fixedly installed and can reciprocate simultaneously when the belt 11 reciprocates horizontally. The member to be sensed 600 is formed of an opaque material that can be recognized by the sensor member 700 by blocking or reflecting the light emitted from the sensor member 700 to be described later so as not to interfere with the tensile force of the belt 11 It is preferable to form it into a thin plate shape having a light weight.

The sensor member 700 is installed on the base plate 110 and detects a member to be detected 600 provided on the belt 11. The sensor member 700 includes a first malfunction detection sensor 710 installed and sensed so as to be spaced apart from one side of the first support member 200 and a second erroneous operation detection unit 710 installed to be spaced apart from one side of the second support member 300, A count sensor 730 may be provided between the sensor 720 and the first malfunction detection sensor 710 and the second malfunction detection sensor 720 to count the number of times the belt 11 is operated

As shown in FIG. 5, the first malfunction detection sensor 710 and the second malfunction detection sensor 720 are spaced apart from each other by a predetermined distance in the horizontal direction. The control unit 800 is set such that the member to be sensed 600 moves horizontally only between the first malfunction detection sensor 710 and the second malfunction detection sensor 720 and is sensed each time the reciprocating movement is performed to the count sensor, To the control member 800 in a state of being connected thereto. The sensor member 700 may be an infrared sensor or an infrared sensor emitting infrared rays or light in the direction of the belt 11.

A support bracket 701 for supporting the first and second erroneous operation detection sensors 710 and 720 and the count sensor 730 may be installed below the sensor member 700 have.

The control member 800 includes a driving sub-operation portion 810 for controlling the operating state of the driving portion 230, a tensile force confirming portion 820 connected to the tension measuring portion 500 to check the tensile force applied to the belt 11, A counter management section 830 for counting and controlling the number of operations of the belt 11 while communicating with the count sensor 730 and a control section 830 for checking the operation state of the belt 11 while communicating with the first and second malfunction detection sensors 710, And a display unit 850 for displaying the operating states of these units. In addition, the control member 800 may include a warning light or a speaker that can be visually easily seen by the user when the belt 11 or the first and second felts 12 and 13 are defective.

5, three or more first poly (12) may be fixed on the rotation axis 220 of the first supporting member 200 by using one driving member 230 in the above- And the belt 11 is attached to the first poly 12 and the second poly 13 in a state where the second supporting member 300 is provided at a position corresponding to the first supporting member 200, . Therefore, it is possible to test a plurality of belts 11 by using one driving member 230 during a test period.

Hereinafter, an operation state of the durability testing apparatus of the belt 11 according to the first embodiment of the present invention will be described.

The first poly 12 is bonded to the rotating shaft 220 of the first supporting member 200 provided inside the case 100 with the first and second poly 12 and 13 to be tested and the belt 11, The second poly 13 is bonded to the poly fixing part 310 of the second supporting member 300 and then one end of the belt 11 is connected to the first poly 12 and the other end is connected to the second poly 13 Connect. At this time, according to the length of the belt 11, the poly fixing unit 310 of the second supporting member 300 is moved through the guide unit 320 and adjusted to a position corresponding to the length of the belt 11, The control box 410 is tightened in the direction of the male screw portion 420 by adjusting the male screw portion 420 of the position fixing member 400 in order to provide tensile force to the belt 11, The tensile force output from the tensile force confirming unit 820 of the control member 800 to the display unit 850 can be monitored and provided to the belt 11 by a desired tensile force.

Thereafter, the operating member is operated in the driving sub-operation portion 810 of the control member 800 so that the driving member 230 is repeatedly rotated in the forward and reverse directions to rotate the rotation shaft 220 of the first supporting member 200 The first poly 12 coupled to the rotating shaft 220 also rotates together and the belt 11 reciprocates horizontally in the left and right directions by the first poly 12, And is simultaneously rotated by the belt 11.

Here, the member to be detected 600 provided on the belt 11 is repeatedly horizontally moved in the interval between the first and second malfunction detection sensors 710 and 720, The counting unit 830 of the control member 800 counts the number of times the sensor unit 730 is sensed when it is repeatedly contacted with the light of the counter sensor unit 730 while reciprocally moving. When the belt 11 is stretched or the durability of the belt 11 is weakened during the test process, the movement distance of the member to be sensed 600 is changed, and the first malfunction detection sensor 710 and the second malfunction detection sensor 720, The control unit 800 sends a signal to the malfunction confirmation unit 840 while the detected member 600 is shifted to the outside of the first malfunction detection sensor 710 or the second malfunction detection sensor 720 When the failure confirmation unit 840 confirms the signal, the test state is transmitted to the display unit 850, so that the display unit 850 can confirm both sides.

As described above, the present invention provides an optimal environmental condition to be tested, and the test is performed simultaneously with the first and second poly (12), (13) and the belt (11) of the elevator door drive apparatus mounted side by side. The present invention can be said to be a very useful invention which can be widely applied to a manufacturing company manufacturing a product related to an elevator door.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, and that the scope of the present invention will be defined by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

10: elevator door driving device 11: belt
12: first poly 13: second poly
100: Case 110: Base plate
200: first pedestal 210: support
300: second pedestal 310: polygonal portion
320: guide part 400: position fixing member
410: Adjustment box 420: Male threads
430: fixed bracket 500: tensile force measuring unit
600: Detected member 700: Sensor member
710: first malfunction detection sensor 720: second malfunction detection sensor
730: Counter sensor 800: Control member

Claims (13)

A case 100 in which an elevator door driving apparatus 10 composed of a belt 11, a first poly 12 connected to one end of the belt and a second poly 13 connected to the other end of the belt 11 is accommodated ,
A support shaft 210 fixed to the upper surface of one side of the base plate 110, a rotation shaft 220 penetratingly coupled to the support 210 and provided with the first poly 12, and a driving unit 230 rotating the rotation shaft The first supporting member 200,
A polypropylene block 310 which is located on the upper surface of the other side of the base plate 110 of the case 100 to fix the second polypropylene 13 rotatably and a guide part 320 which moves the polypropylene block 310, A second supporting member 300 made of a metal,
A position fixing member 400 for tightly fixing the belt 11 connected to the second poly 13 by moving the poly fixing unit 310 of the second supporting member 300,
A tensile force measuring unit 500 installed between the position fixing member 400 and the second supporting member 300 and measuring a tensile force pulling the polychamber unit 310 from the position fixing member 400;
A member to be detected 600 installed on the belt 11 of the elevator door driving apparatus 10 and horizontally moving together when the belt 11 reciprocates horizontally left and right,
A first malfunction detection sensor 710 installed to be spaced apart from one side of the first supporting member 200 and sensing a member to be sensed 600 moving in one direction and a second malfunction detection sensor 710 installed to be spaced apart from a side of the second supporting member 300 A second malfunction detection sensor 720 for sensing a member to be detected 600 moving in the other direction and a second malfunction detection sensor 720 disposed between the first malfunction detection sensor 710 and the second malfunction detection sensor 720, A sensor member 700 composed of a count sensor 730 for counting the number of times,
When the driven member 600 is detected by the first malfunction detection sensor 710 and the second malfunction detection sensor 720 by controlling the driving unit 230 of the first supporting member 200, And a control member (800) for confirming whether or not a failure occurs in the elevator door driving apparatus. The apparatus according to claim 1, wherein a plate-shaped base plate (110) is provided under the case (100). The support unit 210 according to claim 1, wherein the support unit 210 is provided with a through hole 211 passing through both sides thereof, and a bearing unit 230 is provided between the through hole 211 and the rotation axis 220 so as to be rotatable. A durability test apparatus of an elevator door driving apparatus. 4. The apparatus of claim 3, wherein the through hole (211) of the support base (210) is provided with an upper lid (212) which is opened at the upper side and closes the opened portion, And the durability test apparatus of the elevator door driving apparatus. The method according to claim 1, The polychorusment unit 310 includes a lower plate 311 horizontally installed on the upper surface of the other side of the base plate 110 and a lower plate 311 extending upwardly from the upper surface of the lower plate 311, A through hole 313 formed in the rear surface of the side wall plate 312 and a rotation pin 220 'inserted and fixed in the through hole 313 and a through hole 313 and a rotation pin 220 The bearing device according to claim 1, further comprising: The guide unit 320 includes a guiding block 321 formed on a rear surface of a lower plate 311 of the polychoron 310 and a guide 320 installed horizontally on the base plate 110 of the case 100 corresponding to the guide block 321. [ And a rail (322). The position fixing member 400 includes an adjustment box 410 which is located outside the second support member 300 and is connected to the second support member 300 while being spaced apart from the base plate 110, A fixing bracket 430 fixed to the base plate 110 at an outer side of the adjustment box 410 and a fixing bracket 430 fixed at one end to the adjustment box 410 and the other end rotated through the fixing bracket 430, 410) is horizontally moved in the direction of the fixing bracket (430). [Claim 6] The apparatus according to claim 7, wherein the control box (410) is formed in a rectangular shape having an inner space and spaced apart from the polyhedral fastener (310) by a predetermined distance, a through hole (411) And a screw hole (412) formed in the lower portion of the elevator door driving device. The elevator door driving apparatus according to claim 7, wherein a connection rod (440) is formed to connect the control box (410) and the poly-retaining member (310) of the second supporting member (300) Experimental apparatus. The fixing bracket according to claim 7, wherein the fixing bracket (430) is formed with a through hole (431) such that the male screw portion (420) is penetrated and supported, and the diameter of the through hole (431) Wherein the elevator door driving device is installed so as to be capable of idling. The durability test apparatus of claim 1, wherein the member to be detected (600) is made of an opaque material and is formed in a thin plate shape having a light weight so as not to interfere with the tensile force of the belt (11) . The support brackets 701 for supporting the first and second erroneous operation detection sensors 710 and 720 and the count sensor 730 are disposed below the sensor member 700 at a predetermined height from the base plate 110 Wherein the elevator door driving device is mounted on a vehicle. The control unit according to claim 1, wherein the control member includes a driving unit operable to control an operation state of the driving unit, a driving force control unit connected to the tension measuring unit and configured to detect a tensile force applied to the belt, A counter management section 830 for counting and controlling the number of operations of the belt 11 while communicating with the count sensor 730 and a counter 1130 for counting and controlling the number of operations of the belt 11 while communicating with the first and second malfunction detection sensors 710 and 720, A failure confirmation unit 840 for confirming the operating state of the elevator door driving apparatus, and a display unit 850 for displaying the operating states of the elevator door driving apparatus.

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