Mechanical lock used in elevator door systems with telescopic or central doors

The bidirectional mechanical lock system addresses the inefficiencies and safety issues of unidirectional elevator door systems by providing a dual-directional locking mechanism with enhanced safety and adaptability, reducing accidents and resource wastage.

WO2026147481A1PCT designated stage Publication Date: 2026-07-09

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Filing Date
2025-12-30
Publication Date
2026-07-09

AI Technical Summary

Technical Problem

Current elevator door systems require separate mechanisms for right-hand and left-hand locking, leading to inefficiencies, confusion, and safety risks due to direction dependency, resulting in accidents, resource wastage, and operational failures.

Method used

A bidirectional mechanical lock system that operates in both directions, ensuring full contact of the safety circuit and allowing for easy installation and adjustment, compatible with both telescopic and central doors, with features like angular and linear movements, and directional indicators.

Benefits of technology

The bidirectional lock system enhances safety, reduces production and installation complexities, and prevents accidents by ensuring complete locking and contact, while being adaptable to existing systems.

✦ Generated by Eureka AI based on patent content.

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Abstract

The present invention relates to a mechanical lock that can be used in both directions on telescopic and central doors on floor door mechanisms in elevator systems. The present invention particularly relates to a mechanical lock comprising; a lock main body (110), which comprises a central bearing (113) used in performing circular movements, supports the lock system with the central bearing (113), and locks the lock counter connection element (150) with the bidirectional lock elements (111) connected to the same that perform angular movement, and is used in activating and deactivating the contact safety circuit, a movement distributor (120) that can move back and forth with the main lock body (110), provides angular movement to the bidirectional lock elements (111), and is used in the mechanical locking and unlocking of bidirectional lock elements (111), also provides linear back and forth movement capability to the safety plug section, thus both performing mechanical locking and activating the contact safety circuit, bidirectional first movement element (140) that initiates the movement of the locking system, an element for converting circular movement into linear movement (130) used for converting the circular movement received from the bidirectional first movement element (140) into linear movement and a lock counter connection element (150) that acts as the mechanical locking counterpart of the bidirectional lock elements (111) in the final closure in the lock system.
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Description

[0001] MECHANICAL LOCK USED IN ELEVATOR DOOR SYSTEMS WITH TELESCOPIC OR CENTRAL DOORS

[0002] FIELD OF THE INVENTION

[0003] The present invention relates to a mechanical lock that can be used in both directions on telescopic and central doors on floor door mechanisms in elevator systems.

[0004] The present invention particularly relates to a mechanical lock comprising; a lock main body, which comprises a central bearing used in performing circular movements, supports the lock system with the central bearing, and locks the lock counter connection element with the bidirectional lock elements connected to the same that perform angular movement, and is used in activating and deactivating the contact safety circuit, a movement distributor that can move back and forth with the main lock body, provides angular movement to the bidirectional lock elements, and is used in the mechanical locking and unlocking of bidirectional lock elements, also provides linear back and forth movement capability to the safety plug section, thus both performing mechanical locking and activating the contact safety circuit, the bidirectional first movement element that initiates the movement of the locking system, an element for converting circular movement into linear movement used for converting the circular movement received from the bidirectional first movement element into linear movement and a lock counter connection element that acts as the mechanical locking counterpart of the bidirectional lock elements in the final closure in the lock system.

[0005] PRIOR ART

[0006] The working principle of mechanical lock and safety circuit components on elevator automatic door systems used today has become direction-dependent on doors, with R for right and L for left, therefore, direction dependency in production for right and left has resulted in two groups. Therefore, separate mechanisms are produced for the two directions. This results in losses of time, energy, manpower, and resources.Modern elevator automatic landing doors feature mechanical locks that are compatible with either right-hand or left-hand locking, offering a single-point mechanical locking capability. This situation leads to inadequate safety contact and lock systems at the floor doors on the site. The elevator system activates the elevator upon sensing that the safety circuit is complete, when the elevator is in movement, contact with the elevator door or manual intervention may cause the mechanical lock to fail or malfunction, resulting in situations such as the elevator getting stuck between floors at high speed or sudden braking. These negative outcomes lead to elevator accidents resulting in injuries and fatalities.

[0007] In existing door systems, situations such as the door opening as a result of unauthorized external intervention due to the mechanical lock not functioning properly, the elevator system becoming out of service even if there are no passengers in the cabin, and the need for an authorized service technician to intervene in order for the elevator to become operational again result in losses of time and manpower.

[0008] In existing elevator automatic door systems, the production of lock plug contact elements in two separate categories, either right or left, leads to confusion regarding direction during shipping and packaging, resulting in inconvenience and time and financial losses.

[0009] As current elevator automatic door systems are unidirectional, elevator companies and elevator retailers are forced to maintain two separate stock groups for left and right doors. When demand in one area exceeds market demand, leading to insufficient stock, meeting that demand requires time and effort.

[0010] Today, problems arise from the fact that automatic elevator door systems sent for onsite installation are dependent on a single direction, there is confusion regarding the correct direction during packaging, inconsistencies in shipping or architectural projects, telescopic doors being suitable for one direction (R right or L left) but not the other, and shipments being made in the wrong direction.In current systems, since the key mechanisms and operating procedures are very similar, competition can only be achieved through processes such as material thinning, reduction, and the use of insufficient spare parts. This situation poses a significant risk both in the field and to end-users, and is the cause of fatal accidents that have been reported in the media recently.

[0011] In current technology, the activation of safety circuits is determined solely by the opening and closing of locks and safety contacts using stop buffers. This situation causes the mechanical locking system to fail to lock completely, or the safety circuit plug to fail to make full contact with the opposite contact. Field malfunctions occur because both the mechanical lock and the safety circuit are positioned only according to the buffer distance.

[0012] As a result, the need for an economically viable, efficient elevator automatic door to solve the problems existing in the current technology and mentioned above, along with the inadequacy of existing solutions, has necessitated technical advancement in this field.

[0013] OBJECT OF THE INVENTION

[0014] With this invention, the bidirectional lock system in telescopic door mechanisms is produced in a single type. In this way, it is used as a single type of locking and safety system that can operate in both directions, regardless of whether R is the right or L is the left.

[0015] Another object of the present invention is to double the security feature with its mechanical locking system. During mechanical locking, the safety plug portion gains linear movement, while the bidirectional lock elements that perform mechanical locking provide mechanical locking from below and above with limited circular movement, and the safety circuit is activated as a result of the plug portion's contact with the contact part. This ensures full contact of the elevator safety circuit, preventing elevator accidents.

[0016] Another object of the present invention is to enable the safety plug and the safety circuit contact counterpart in the newly developed system to be used bi-directionally.Another object of the present invention is to eliminate problems such as right- or lefthand design part incompatibility, and to provide great opportunities and convenience in production, since it is a locking and safety system that can operate in both R and L directions in production.

[0017] Another object of the present invention is to enable the application of the non-directional locking system in both telescopic door mechanisms and central doors. This eliminates problems such as orientation confusion in packaging, while preventing energy, time, and manpower losses in production.

[0018] Another object of the present invention is to enable installers to see which direction they are installing the product by placing R and L (right and left) direction symbols on the product, thus facilitating installation.

[0019] The most important aspect of the present invention is its ability to easily adapt to existing systems with its non-directional R-to-right and L-to-left telescopic door mechanism. As it offers adjustment options, it can be applied to all elevator cabin door systems.

[0020] A further object of the present invention is to allow the locking and safety system to be opened and closed as desired, thus ensuring full contact of the plug and active operation of the safety circuit, thereby ensuring elevator safety.

[0021] Another object of the present invention is to allow the manual locking of the door to be opened from the outside in both directions (R and L) using a bidirectional latch located in the central locking mechanism, even when the telescopic folding door mechanism is mounted by turning it in the R and L directions.

[0022] In this invention, downward pushing is achieved by attaching metal weights to the movement limits of the feet, and this system also allows it to operate in central floor door mechanisms.FIGURES CLARIFYING THE INVENTION

[0023] FIGURE-1; is a front perspective view of the mechanical lock of the present invention.

[0024] FIGURE-2; is a rear perspective view of the mechanical lock of the present invention.

[0025] FIGURE-3; is a disassembled perspective view of the mechanical lock of the present invention.

[0026] FIGURE-4; is a view of the element for converting circular movement into linear movement in the mechanical lock of the present invention.

[0027] FIGURE-5; is a view of the locking system push element in the mechanical lock of the present invention.

[0028] REFERENCE NUMBERS

[0029] 110. Lock Main Body

[0030] 111. Bidirectional Lock Element

[0031] 111.1. Angle bearings

[0032] 112. Movement Stopping Buffers

[0033] 113. Central Bearing

[0034] 114. Lock System Push Element

[0035] 114.1. Lock Adjustment Pin

[0036] 114.2. Inner Spring

[0037] 114.3. Outer Spring

[0038] 114.4. Outer Body

[0039] 114.5. Front Connection Pin

[0040] 115. Lock Manual Release Latch

[0041] 120. Movement Distributor

[0042] 121. Lock Element Angular Movement Bearing

[0043] 122. Push Element Contact Area

[0044] 123. Non-directional Channel124. Plug Connection Element

[0045] 130. Element for Converting Circular Movement into Linear Movement

[0046] 131. Movement Limit Feet

[0047] 132. Direction Symbol

[0048] 133. Back and Forth Movement Pin

[0049] 140. Bidirectional First Movement Element

[0050] 141. Direction Window

[0051] 142. Bidirectional Use Slot Channels

[0052] 150. Lock Counter-Contact Connection Element

[0053] 151. Safety Circuit Contact Counterpart

[0054] DETAILED DESCRIPTION OF THE INVENTION

[0055] The invention, shown from different angles in Figure-1 , Figure-2, and Figure-3, in its most general form comprises the lock main body (110), movement distributor (120), element for converting circular movement into linear movement (130), bidirectional first movement element (140), and lock counter-contact connection element (150). Figure 1 shows the invention from the front perspective, and Figure 2 shows it from the rear perspective. In the present invention, the lock main body (110) houses the main parts: the movement distributor (120), the element for converting circular movement into linear movement (130) and the bidirectional first movement element (140). The central bearing (113) located in the center of the lock main body (110) allows the other elements to be mounted thereon. It restricts movement thereon with movement limiting buffers (112) located on its rear.

[0056] The bidirectional lock elements (111), shown assembled in Figure-1 and disassembled in Figure-3, are used to lock the lock main body (110) to the lock counter-contact element (150) and to ensure the safe operation of the contact safety circuit. The bidirectional lock elements (111) are connected to the lock main body (110). Bidirectional lock elements (111) also have angle bearings (111.1). These angle bearings (111.1) are positioned on the angular movement bearings (121) which are the lock element formed on the movement distributor (120). Lock elementangular movement bearings (121) are bearings that are opened by giving an angle. These angle bearings (111.1) on the bidirectional lock elements (111) are positioned in the angular movement bearings (121) of these locking elements and enable the angular movement of the bidirectional lock elements (111) together with the linear movement of the movement distributor (120). With this angular movement, the bidirectional lock elements (111) are positioned to lock onto the lock counter-contact connection element (150).

[0057] The movement distributor (120) in the invention is the element that can move back and forth on the lock main body (110) and gives angular movement to the bidirectional lock elements (111) described above with its angular movement bearings (121) and is used in the mechanical locking and unlocking of the bidirectional lock elements (111). The movement distributor (120) comprises a plug connection element (124). The safety plug portion is located on the plug connection element (124). The movement distributor (120) is the element that both performs mechanical locking and activates the contact safety circuit with the safety circuit contact counterpart (151) and the contact of the safety plug, as it provides linear back-and-forth movement capability to the safety plug portion. Again, there is a non-directional channel (123) on the movement distributor (120). With this non-directional channel (123), the linear movement of the movement distributor (120) is enabled. The back and forth linear movement of the movement distributor (120) is provided by the back and forth movement of the back and forth movement pin (133) in the element for converting circular movement into linear movement (130), within these non-directional channels (123).

[0058] In the invention, the element for converting circular movement into linear movement (130), as detailed in Figure-4, converts the circular movement it receives from the bidirectional first movement element (140) into linear movement in the movement distributor (120) with the back and forth movement pin (133) thereon. In addition, the movement limit feet (131) located at the rear of this circular movement, which it receives from the bidirectional first movement element (140), impose a limitation thereon.The bidirectional first movement element (140) is the element that transmits the movement it receives from the cabin door operator, which initiates the movement of the locking system, to the lower organs and can be used in both directions with the circularly opening bidirectional use slot channels (142) thereon, and shows which direction it moves with the help of the direction windows (141) thereon.

[0059] Locking the bidirectional lock elements (150) to the lock counter contact connection element (111) with this angular movement, It is also the element on which the safety circuit contact counterpart (151) is located.

[0060] The lock system push element (114), detailed in Figure-5 of the present invention, is the element used to reverse the backward force that the movement distributor (120) in the bidirectional lock group takes on during its linear movement when locking. Lock system push element (114) comprises; lock adjustment pin (114.1.), inner spring (114.2.), outer spring (114.3.), external body (114.4.) and front connection pin (114.5.). The lock adjustment pin (114.1) is used for back and forth fine adjustment of the movement distributor (120). The inner spring (114.2) and the outer spring (114.3) are used to create a counterforce to the force applied to the back opening movement of the movement distributor (120). The outer body (114.4.) is the element that serves as the counterpart to the lock adjustment pin (114.1.), and thanks to its grooved structure inside, the lock adjustment pin (114.1.) moves within the same during precise adjustment. The front connection pin (114.5.) is the element on which the outer housing (114.4.) rests after the lock adjustment pin (114.1.) moves inside the outer body (114.4.) and is used to ensure and guide the precise movement of the element for converting circular movement into linear movement (130).

[0061] The manual lock release latch (115) is an element that allows authorized personnel to intervene in the system, which is installed on the floor door frames and operates with the help of authorized personnel and a key, from outside. The lock manual release latch (115) is the element that enables the lock system to be opened and the contact safety circuit to be interrupted by the cyclical movement of the central bearing (113) which is mounted on the central bearing (113) located on the lock main body (110).In the operation of the bidirectional elevator locking system in the invention, the cabin door operator transmits the movement received from the sword system to the bidirectional first movement element (140). The circular movement coming to the first bidirectional movement element (140) is transferred to the element for converting the circular movement into linear movement (130) via the central bearing (113). Back and forth movement pin (133) on the element for converting circular movement into linear movement (130) moves in the non-directional channels (123) created on the movement distributor (120), thus gives the movement distributor (120) movement in the linear direction. Limited angular movement of the bidirectional lock elements (111) is performed with the angular movement bearings (121) of the locking element located on the movement distributor (120). This movement is achieved by moving the angular bearings (111.1) on the bidirectional lock elements (111) inside the lock element angular movement bearings (121). This angular movement is used in unlocking and closing the bidirectional lock elements (111). At the same time, the safety plug in the plug connection element (124) on the movement distributor (120) is connected to the safety circuit contact counterpart (151) in the lock counter contact connection element (150) and the contact safety circuit is activated. The lock system push element (114) located on the lock main body (110) allows the back and forth adjustment of the movement distributor (120). This ensures that the safety plug in the contact safety circuit and the safety circuit contact counterpart (151) are in full contact with each other and provides the possibility of precise adjustment so that the bidirectional lock elements (111) can lock completely.

[0062] The circular movement from the bidirectional first movement element (140) is transferred to the element for converting circular movement into linear movement (130) via the central bearing (113), while the movement limit feet (131) and movement stopping buffers (112) are used to limit this circular movement. With the circular movement coming from the first bidirectional movement element (140), the movement limit feet (131) at the rear of the element for converting the circular movement into linear movement (130) rest on the movement stopping buffers (112) on the lock main body (110). Thus, the circular movement is limited.

[0063] The bidirectional locking system can be positioned either R (right) or L (left) on the floor door mechanism, depending on the cabin door operator's direction of operation.The direction of this positioning can be understood from the direction windows (141) on the first bidirectional element (140) when the bidirectional lock and safety group is mounted. The direction is also shown visually with the direction windows (141) where R is in the right or L is in the left position. The information that R is in the right or L is in the left position is also indicated by the direction symbols (132) on the element for converting circular movement into linear movement (130).

[0064] Said mechanical locking system can switch to the R right position or the L left position or the L left position to the R right position with the help of the bidirectional slot channels (142) on the bidirectional first movement element (140) and the bidirectional use of the element for converting circular movement into cyclical movement (130), in order to take the appropriate position for the telescopic floor door mechanism positioning direction.

[0065] In brief, the present invention is a mechanical lock system that can be used in both directions on telescopic and central doors on floor door mechanisms in elevator systems. In the system of the present invention, comprising; a lock main body (110), which comprises a central bearing (113) used in performing circular movements, supports the lock system with the central bearing (113), and locks the lock counter connection element (150) with the bidirectional lock elements (111) connected to the same that perform angular movement, and is used in activating and deactivating the contact safety circuit, a movement distributor (120) that can move back and forth on the main lock body (110), provides angular movement to the bidirectional lock elements (111) via the lock element angular movement bearings (121) thereon, and is used in the mechanical locking and unlocking of bidirectional lock elements (111), also provides linear back and forth movement capability to the safety plug portion, thus both performing mechanical locking and activating the contact safety circuit, bidirectional first movement element (140) that initiates the movement of the locking system, element for converting circular movement into linear movement (130), which is used for converting the circular movement received from the bidirectional first movement element (140) into linear movement, and also limits this circular movement received from the bidirectional first movement movement element (140) with the movement limit feet (131) located at the back, compatible with both right and left-hand doors, usable in both directions and a lock counter connection element(150) which acts as the mechanical locking counterpart of the bidirectional lock elements (111 ) in the final closing of the lock system.

[0066] The present invention comprises angle bearings (111.1) that are positioned on the angular movement bearings (121) of the lock element formed by giving an angle in the movement distributor (120) on the bidirectional lock elements (111) in the lock main body (110) of the invention, to enable the angular movement of the bidirectional lock elements (111) together with the linear movement of the movement distributor (120). Again, there are movement stopping buffers (112) in the lock main body (110), which transfers the circular movement from the bidirectional first element (140) to the element for converting the circular movement into linear movement (130) via the central bearing (113), while the limiting of this circular movement is ensured by the element, is the point of support in limiting the circular movement coming from the bidirectional first movement element (140) by using the movement limit feet (131) at the rear of the element for converting the circular movement into linear movement (130) and brings limit to this circular movement. In said lock main body (110), there is a lock system push element (114) which acts as a reverse pusher and can limit the movement of the movement distributor (120) in the bidirectional lock group during its linear movement, and also allows for the precise back and forth adjustment of the movement distributor (120), ensuring that the safety plug in the contact safety circuit and the safety circuit contact counterpart (151) are in full contact and that the bidirectional lock elements (111) can be fully locked. Said lock system push element (114) includes; lock adjustment pin (114.1) used for making the back and forth fine adjustment of the movement distributor (120), inner spring (114.2) and outer spring (114.3) which are used to create a counterforce to the force applied to the back opening movement of the movement distributor (120), outer body (114.4), which is used as the counterpart of the lock adjustment pin (114.1.), and in which the lock adjustment pin (114.1.) moves during precise adjustment with its grooved structure therein, front connection pin (114.5) on which the outer body (114.4) rests after the lock adjustment pin (114.1) moves inside the outer body (114.4) and which is used to ensure and guide the precise movement of the movement distributor (120). The lock manual release latch (110) also includes lock manual opening latch (115), which is mounted on the central bearing (113) located on the lock main body (110) and is used to enable the lock system to be opened and the contact safety circuit to be cutby the cyclical movement of the central bearing (113), allowing external intervention by authorized personnel into the system which is operated with the help of authorized personnel and a key attached to the door frames.

[0067] Another element in the invention is the movement distributor (120) element. The movement distributor (120) includes push element contact area (122) thereon where the lock system push element (114) is located and which is used to transmit the movement it receives by relying on the lock system push element (114) during adjustment to the movement distributor (120). There is also a non-directional channel (123) used to perform the back and forth linear movement of the movement distributor (120) by moving inside the back and forth movement pin (133) of the element for converting circular movement into linear movement (130), which is created on the movement distributor (120). In addition, the movement distributor (120) has a plug connection element (124) for positioning the safety plug portion.

[0068] Another element in the present invention is the element for converting circular movement into linear movement (130). The bidirectional lock system created on the element for converting circular movement into linear movement (130) has direction symbols (132) that indicate whether the cabin door operator's working direction is on the right (R) or left (L) position. In addition, there is a back and forth movement pin (133) which is formed on the element for converting circular movement into linear movement (130), is used to convert the circular movement received from the bidirectional first movement element (140) into linear movement in the movement distributor (120).

[0069] Again, the bidirectional first movement element (140) in the present invention can be used in both directions compatible with the right and left floor doors with its circularly opening bidirectional use slot channels (142) and can show which direction it moves with the help of its directional windows (141).

[0070] Another element in the invention, the lock counter contact connection element (150), comprises a safety circuit contact counter (151) on which the safety plug can be made to contact the safety circuit contact counter (151) when the bidirectional lock elements (111) are locked to said lock counter contact connection element (150) at the final closing of the lock system.The mechanical locking mechanism described in the invention operates using the following steps: the cabin door operator transmitting the movement received from the sword system to the bidirectional first movement element (140), transferring the circular movement coming to the first bidirectional movement element (140) to the element for converting the circular movement into linear movement (130) via the central bearing (113), the back and forth movement pin (133) on the element for converting circular movement to linear movement (130) moving in the non-directional channels (123) created on the movement distributor (120), thus giving the movement distributor (120) movement in the linear direction, performing limited angular movement of the bidirectional lock elements (111) with the angular movement bearings (121) of the locking element located on the movement distributor (120), locking the bidirectional lock elements (111) to the lock counter contact connection element (150) with this angular movement, the safety plug on the plug connection element (124) on the movement distributor (120) being connected to the safety circuit contact counterpart (151) on the lock counter contact connection element (150) during the locking process, activating the contact safety circuit, ensuring the angular movement of the bidirectional lock elements (111) in the unlocking process, disconnecting the safety plug from the safety circuit contact (151), deactivating the contact safety circuit.

[0071] This invention can be used in all telescopic and central landing floor door mechanisms produced today, in building entrance photocell doors, in automation systems requiring zero errors in movement, and in robotic gripping and lifting systems.

Claims

CLAIMS1. A mechanical lock system that can be used in both directions on telescopic and central doors on floor door mechanisms in elevator systems, characterized by comprising;• a lock main body (110), which comprises a central bearing (113) used in performing circular movement, supports the lock system with said central bearing (113), and locks the lock counter connection element (150) with the bidirectional lock elements (111) connected to the same that perform angular movement, and is used in activating and deactivating the contact safety circuit, • a movement distributor (120) that can move back and forth on the main lock body (110), provides angular movement to the bidirectional lock elements (111) via the lock element angular movement bearings (121) thereon, and is used in the mechanical locking and unlocking of bidirectional lock elements (111), also provides linear back and forth movement capability to the safety plug portion, thus both performing mechanical locking and activating the contact safety circuit,• bidirectional first movement element (140), which transmits the movement received from the cabin door operator, initiates the movement of the locking system, to the lower organs,• element for converting circular movement into linear movement (130), which is used for converting the circular movement received from the bidirectional first movement element (140) into linear movement, and also limits this circular movement received from the bidirectional first movement element (140) with the movement limit feet (131) located at the back, compatible with both right and left-hand doors, usable in both directions,• lock counter connection element (150) which acts as the mechanical locking counterpart of the bidirectional lock elements (111) in the final closing of the lock system.

2. Lock main body (110) according to claim 1, characterized by comprising angle bearings (111.1) formed on said bidirectional lock elements (111), used to enable the bidirectional lock elements (111) to perform angular movementtogether with the linear movement of said movement distributor (120) by positioning said lock element (121 ) in said movement distributor (120).

3. Lock main body (110) according to claim 1, characterized by comprising movement stopping buffers (112) in the lock main body (110), which transfers the circular movement from said bidirectional first element (140) to the element for converting the circular movement into linear movement (130) via the central bearing (113), while the limiting of this circular movement is ensured by the element, is the point of support in limiting the circular movement coming from the bidirectional first movement element (140) by using the movement limit feet (131) at the rear of the element for converting the circular movement into linear movement (130) and brings limit to this circular movement.

4. Lock main body (110) according to claim 1, characterized by comprising a lock system push element (114) on said lock main body (110) which acts as a reverse pusher and can limit the movement of the movement distributor (120) in the bidirectional lock group during its linear movement, and also allows for the precise back and forth adjustment of the movement distributor (120), ensuring that the safety plug in the contact safety circuit and the safety circuit contact counterpart (151) are in full contact and that the bidirectional lock elements (111) can be fully locked.

5. Lock system push element (114) according to claim 1, characterized by comprising;• lock adjustment pin (114.1) which is used for back and forth fine adjustment of the movement distributor (120),• inner spring (114.2) and the outer spring (114.3), which are used to create a counterforce to the force applied to the back opening movement of the movement distributor (120),• outer body (114.4), which is the element that serves as the counterpart to the lock adjustment pin (114.1.), and thanks to its grooved structure inside, the lock adjustment pin (114.1.) moves within the same during precise adjustment, • front connection pin (114.5) is the element on which the outer housing (114.4) rests after the lock adjustment pin (114.1) moves inside the outer body(114.4) and is used to ensure and guide the precise movement of the movement distributor (120).

6. Lock main body (110) according to claim 1 , characterized by comprising lock manual opening latch (115), which is mounted on the central bearing (113) located on the lock main body (110) and is used to enable the lock system to be opened and the contact safety circuit to be cut by the cyclical movement of the central bearing (113), allowing external intervention by authorized personnel into the system which is operated with the help of authorized personnel and a key attached to the doorframes.

7. Movement distributor (120) according to claim 1 , characterized by comprising push element contact area (122) on said movement distributor (120) where the lock system push element (114) is located and which is used to transmit the movement it receives by relying on the lock system push element (114) during adjustment to the movement distributor (120).

8. Movement distributor (120) according to claim 1 , characterized by comprising a non-directional channel (123) used to perform the back and forth linear movement of the movement distributor (120) by moving inside the back and forth movement pin (133) of the element for converting circular movement into linear movement (130), which is created on the movement distributor (120).

9. Movement distributor (120) according to claim 1 , characterized by comprising a plug connection element (124) on said movement distributor (120) for positioning the safety plug portion.

10. Element for converting circular movement into linear movement (130) according to claim 1, characterized by comprising direction symbols (132) on said element for converting circular movement into linear movement (130) that indicate whether the cabin door operator's working direction is on the right (R) or left (L) position.

11. Element for converting circular movement into linear movement (130) according to claim 1, characterized by comprising a back and forth movement pin (133) which is formed on the element for converting circular movement into linear movement (130), is used to convert the circularmovement received from the bidirectional first movement element (140) into linear movement in the movement distributor (120).

12. Bidirectional first movement element (140) according to claim 1, characterized by a bidirectional first movement element (140) that can be used in both directions compatible with the right and left floor doors with circularly opening bidirectional use slot channels (142) thereon, and shows which direction it moves with the help of directional windows (141) thereon.

13. Lock counter contact connection element (150) according to claim 1, characterized by comprising a safety circuit contact counter (151) on said lock counter contact connection element (150) on which the safety plug can be made to contact the safety circuit contact counter (151) when the bidirectional lock elements (111) are locked to said lock counter contact connection element (150) at the final closing of the lock system.

14. A mechanical lock operating method that can be used in both directions on telescopic and central doors on floor door mechanisms in elevator systems, characterized by comprising the process steps of;• cabin door operator transmitting the movement received from the sword system to the bidirectional first movement element (140),• transferring the circular movement coming to the first bidirectional movement element (140) to the element for converting the circular movement into linear movement (130) via the central bearing (113), • back and forth movement pin (133) on the element for converting circular movement into linear movement (130) moving in the non- directional channels (123) created on the movement distributor (120), thus giving the movement distributor (120) movement in the linear direction,• performing limited angular movement of the bidirectional lock elements (111) with the angular movement bearings (121 ) of the locking element located on the movement distributor (120),• locking the bidirectional lock elements (111 ) to the lock counter contact connection element (150) with this angular movement,• safety plug on the plug connection element (124) on the movement distributor (120) being connected to the safety circuit contact counterpart (151) on the lock counter contact connection element (150) during the locking process,• activating the contact safety circuit,• ensuring the angular movement of the bidirectional lock elements (111) in the unlocking process,• disconnecting the safety plug from the safety circuit contact (151 ), • activating the contact safety circuit.