CN220376068U - Control unit structure for elevator door - Google Patents

Abstract

The utility model discloses a control unit structure for an elevator door, which comprises a shell mechanism, wherein an output shaft head is arranged on the surface of the shell mechanism, and a controller mechanism is arranged in the shell mechanism; the controller mechanism comprises 24V+ interfaces, 24V-interfaces, SET keys, add keys, subtract keys, a safety loop, a door closing in-place signal, a COM interface, a public end, a door closing signal and other structures. The control unit structure for the elevator door is characterized in that a plurality of structures such as a 24V+ interface, a 24V-interface, a SET key, an add key, a subtract key, a safety loop, a door closing in-place signal, a COM interface, a public end, a door closing signal, a first public end, a door opening signal, synchronous output, a second public end, synchronous input, a third public end, locking completion signal detection, an electric lock unlocking signal, DC12V+ output, DC 12V-output, lamp strip output DC12V-, lamp strip output DC12V+ and the like are arranged to be combined, so that various accurate feedback can be conveniently made when different working conditions are handled, the control diversity and flexibility are improved, and the safety is improved.

Description

Control unit structure for elevator door

Technical Field

The utility model relates to the technical field of elevator equipment, in particular to a control unit structure for an elevator door.

Background

Elevator doors are important elevator devices and are also a very important part of elevators, and generally have two doors, called hall doors, which are fixed to each floor and visible from the outside of the elevator, and called car doors, which are fixed to the car as it moves. The opening and closing of the elevator door is typically a hoistway door opening and closing driven by the car door. Its stability, rationality, safety are key factors in determining the class of elevators. The switching system of the elevator door is realized by a control unit.

The existing elevator door control unit is simple in arrangement, accurate vertical reactions are difficult to make when various subdivision is met, and flexibility in application is poor.

Disclosure of Invention

The utility model provides a control unit structure for an elevator door, which has the advantages of improving the application flexibility and presetting various feedback, and solves the problems that accurate and vertical reactions are difficult to make when various subdivision is performed, and the flexibility in application is poor.

The utility model provides the following technical scheme: the control unit structure for the elevator door comprises a shell mechanism, wherein an output shaft head is arranged on the surface of the shell mechanism, and a controller mechanism is arranged inside the shell mechanism;

the controller mechanism comprises a 24V+ interface, a 24V-interface, a SET key, a key adding and subtracting, a safety loop, a door closing in-place signal, a COM interface, a public end, a door closing signal, a first public end, a door opening signal, a synchronous output, a second public end, a synchronous input, a third public end, a locking completion signal detection, an electric lock unlocking signal, a DC12V+ output, a DC 12V-output, a lamp strip output DC12V-, a lamp strip output DC12V+, a nixie tube and a motor interface.

Preferably, the SET key is a function key.

Preferably, the safety circuit outputs a closing signal after being locked.

Preferably, the 24v+ interface, 24V-interface and motor interface are provided on one side of the controller mechanism.

Preferably, the safety loop, the door closing in-place signal, the COM interface, the public terminal, the door closing signal, the first public terminal, the door opening signal, the synchronous output, the second public terminal, the synchronous input, the third public terminal, the lock completion signal detection, the electric lock unlocking signal, the DC12v+ output, the DC 12V-output, the lamp strip output DC 12V-and the lamp strip output DC12v+ are arranged on one side of the controller mechanism far away from the SET key.

Preferably, the nixie tube, the SET key, the adding key and the subtracting key are arranged at the top of the controller mechanism.

The utility model has the following beneficial effects:

the control unit structure for the elevator door is characterized in that a plurality of structures such as a 24V+ interface, a 24V-interface, a SET key, an add key, a subtract key, a safety loop, a door closing in-place signal, a COM interface, a public end, a door closing signal, a first public end, a door opening signal, synchronous output, a second public end, synchronous input, a third public end, locking completion signal detection, an electric lock unlocking signal, DC12V+ output, DC 12V-output, lamp strip output DC12V-, lamp strip output DC12V+ and the like are arranged to be combined, so that various accurate feedback can be conveniently made when different working conditions are handled, the control diversity and flexibility are improved, and the safety is improved.

Drawings

FIG. 1 is a schematic diagram of a housing mechanism of the present utility model;

FIG. 2 is a schematic diagram of a controller mechanism according to the present utility model;

fig. 3 is a schematic view of an output shaft head according to the present utility model.

In the figure: 1. 24v+ interface; 2. 24V-interface; 3. a SET key; 4. adding a key; 5. reducing keys; 6. a safety circuit; 7. a door closing in place signal; 8. a COM interface; 9. a public terminal; 10. a door closing signal; 11. a first common terminal; 12. a door opening signal; 13. synchronous output; 14. a second common terminal; 15. a synchronous input; 16. a third common terminal; 17. detecting a locking completion signal; 18. an electric lock unlocking signal; 19. DC12v+ output; 20. DC 12V-output; 21. DC 12V-output by the lamp strip; 22. the lamp strip outputs DC12V+; 23. a nixie tube; 24. and a motor interface.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, a control unit structure for an elevator door includes a housing mechanism, wherein an output shaft head is arranged on the surface of the housing mechanism, and a controller mechanism is arranged inside the housing mechanism;

the controller mechanism comprises a 24V+ interface 1, a 24V-interface 2, a SET key 3, an add key 4, a subtract key 5, a safety loop 6, a door closing in-place signal 7, a COM interface 8, a public terminal 9, a door closing signal 10, a first public terminal 11, a door opening signal 12, a synchronous output 13, a second public terminal 14, a synchronous input 15, a third public terminal 16, a locking completion signal detection 17, an electric lock unlocking signal 18, a DC12V+ output 19, a DC 12V-output 20, a lamp band output DC12V-21, a lamp band output DC12V+22, a nixie tube 23 and a motor interface 24.

In the present utility model, SET key 3 is a function key.

In the present utility model, the safety circuit 6 outputs a closing signal after being locked.

In the present utility model, the 24v+ interface 1, the 24V-interface 2 and the motor interface 24 are provided on one side of the controller mechanism.

In the utility model, a safety loop 6, a door closing in-place signal 7, a COM interface 8, a public terminal 9, a door closing signal 10, a first public terminal 11, a door opening signal 12, a synchronous output 13, a second public terminal 14, a synchronous input 15, a third public terminal 16, a locking completion signal detection 17, an electric lock unlocking signal 18, a DC12V+ output 19, a DC 12V-output 20, a lamp strip output DC12V-21 and a lamp strip output DC12V+22 are arranged on one side of a controller mechanism far away from a SET key 3.

In the utility model, a nixie tube 23, a SET key 3, an add key 4 and a subtract key 5 are arranged at the top of a controller mechanism.

The working principle is that the door opening operation speed of F1 is respectively set to be 0-7, the door opening creep angle range of F2 is 0-40, the door closing operation speed range of F3 is 0-7, the door closing creep angle range of F4 is 0-40, the door opening keeping time of F5 is counted after the door leaf is opened in place, the door leaf is closed after the counted time is up, and the adjustment range is 0-15 seconds; if set as-, the door is closed after the door closing signal is triggered;

setting F6 door-blocking force, when the door is closed, opening the door leaf again, closing the door again after the door is opened for a certain time, adjusting the door-opening angle of F7 to be between 85 and 99, automatically stopping the door after the door-blocking angle reaches the set angle, and adjusting the door-blocking angle to be-;

setting F8 driving/driven to 0 and a single gate; setting 1, and linking a double door with a driving door; setting 2, and linking the driven doors by double doors; f9, starting delay, namely, after power-on, the door is operated in the door closing direction, if the door is operated in the door opening direction, the parameter F is changed, and the motor acts after the delay time is passed after power-on, so that the adjustment range is 0-60; fn, coaxial and arm lever function selection; f0 is set to be 1 to start a demonstration mode (automatic recovery after power failure) E1, wherein the motor transmission fails to check whether the motor is firmly connected with the door body; e2, the motor is not connected; e3, starting up faults, and checking whether the electric lock or other parts have a door clamping condition; e4, motor Hall fault, replacing the motor; e5, checking whether the driven door is normal or not according to the double-door linkage fault, and closing the door in place without display; h1, opening the door;

h2, opening the door and keeping; in the closing process, if the closing process is in place, displaying-c, and checking whether a closing in-place switch is in poor contact; h4, opening the door to meet resistance; h5, closing the door and meeting resistance; and H6, powering up and waiting.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A control unit structure for lift-cabin door, includes casing mechanism, its characterized in that: the surface of the shell mechanism is provided with an output shaft head, and the inside of the shell mechanism is provided with a controller mechanism;

the controller mechanism comprises a 24V+ interface (1), a 24V-interface (2), a SET key (3), an add key (4), a subtract key (5), a safety loop (6), a door closing in-place signal (7), a COM interface (8), a public end (9), a door closing signal (10), a first public end (11), a door opening signal (12), a synchronous output (13), a second public end (14), a synchronous input (15), a third public end (16), a locking completion signal detection (17), an electric lock unlocking signal (18), a DC12V+ output (19), a DC 12V-output (20), a lamp strip output DC12V- (21), a lamp strip output DC12V+ (22), a nixie tube (23) and a motor interface (24).

2. A control assembly structure for an elevator door according to claim 1, wherein: the SET key (3) is a function key.

3. A control assembly structure for an elevator door according to claim 1, wherein: and the safety loop (6) outputs a closing signal after being locked.

4. A control assembly structure for an elevator door according to claim 1, wherein: the 24V+ interface (1), the 24V-interface (2) and the motor interface (24) are arranged on one side of the controller mechanism.

5. A control assembly structure for an elevator door according to claim 1, wherein: the safety circuit (6), the door closing in-place signal (7), the COM interface (8), the public end (9), the door closing signal (10), the first public end (11), the door opening signal (12), the synchronous output (13), the second public end (14), the synchronous input (15), the third public end (16), the locking completion signal detection (17), the electric lock unlocking signal (18), the DC12V+ output (19), the DC 12V-output (20), the lamp strip output DC12V- (21) and the lamp strip output DC12V+ (22) are arranged on one side of the controller mechanism far away from the SET key (3).

6. A control assembly structure for an elevator door according to claim 1, wherein: the nixie tube (23), the SET key (3), the adding key (4) and the subtracting key (5) are arranged at the top of the controller mechanism.