CN111679224A - A kind of detection equipment for elevator bypass device plug group and its detection and assembly method - Google Patents

Abstract

The invention provides a detection device for a plug group of an elevator bypass device, which includes a detection platform and a detection device arranged on the detection platform; A mechanical error-proofing component for identifying errors in the bypass device plug and an electronic error-proofing circuit for detecting whether there is a wrong wiring or short circuit inside the elevator bypass device plug; the detection socket is arranged on the detection platform, and the hole position of the detection socket includes: The connection hole position and the disconnection hole position, the mechanical error-proof part is arranged in the disconnection hole position of the detection socket; the electronic error-proof circuit is connected with the detection socket. The invention also provides a method for detecting and assembling a plug group of an elevator bypass device. The invention can quickly and reliably perform effective detection on each plug of the elevator bypass device plug group, so as to prevent the internal wiring of each plug from being incorrectly connected or the plug identification error, thereby ensuring the continuous output quality of the bypass device plug group.

Description

A kind of detection equipment for elevator bypass device plug group and its detection and assembly method

technical field

The present invention relates to the technical field of elevator accessory detection, and more particularly, to a detection device for a plug group of an elevator bypass device and a detection and assembly method thereof.

Background technique

As a special equipment with rapid growth and frequent use, the number of accidents is also increasing year by year. In order to ensure the safety of the elevator, the elevator bypass device came into being. As a new member of elevator components and functions, the elevator bypass device replaces the short-circuit operation with high risk factor in the past, and increases the safety guarantee for the maintenance and inspection of the operator.

Existing elevator bypass devices are generally provided with normal operation sockets, car door bypass sockets, hall door bypass sockets and/or rear hall door bypass sockets. When working, the function-selected plug is used to connect with the corresponding socket: plug During normal operation, the plug for function selection is connected with the normal operation socket; when the car door is bypassed, the plug is connected with the car door bypass socket; when the hall door is bypassed, the plug is connected with the hall door bypass socket, and the bypass device When in a certain state, operations in other states are restricted, effectively avoiding the risk of misoperation. Therefore, several corresponding plugs will form the elevator bypass device plug group, as the main accessories for elevator maintenance and inspection, and the wiring conditions and quality of each plug in the elevator bypass device plug group will directly affect the elevator bypass device. work performance.

At this stage, the wrong wiring or the wrong combination of plug groups often occurs in the plug group of the elevator bypass device. Because the plugs of the elevator bypass device plug group are all 3 or 4 9-pin AMP plugs, the appearance is the same, but The internal wiring is not the same. Even after the color recognition of the connector wiring is completed, the problem of wrong internal wiring of the plug or incorrect plug identification cannot be prevented from happening again. Therefore, it is now necessary to provide an effective detection equipment for the plug group of the elevator bypass device and a detection and assembling method thereof, so as to ensure the continuous output quality of the plug group of the bypass device, so as to improve the safety of the elevator bypass device in the maintenance and inspection of the elevator. .

SUMMARY OF THE INVENTION

The purpose of the present invention is to overcome the shortcomings and deficiencies in the prior art, and to provide a detection device for the plug group of the elevator bypass device, which can quickly and reliably detect the plugs of the elevator bypass device plug group effectively, so as to prevent Prevent the internal wiring of each plug from being incorrectly connected or the plug identification error, so as to ensure the continuous output quality of the bypass device plug group, and to improve the safety of the elevator bypass device during elevator maintenance and inspection. The invention also provides an efficient and reliable method for detecting and assembling the plug group of the elevator bypass device, thereby improving the efficiency and correct reliability of the assembly of the elevator bypass device plug group.

In order to achieve the above-mentioned purpose, the present invention is realized by the following technical solutions: a detection device for a plug group of an elevator bypass device, characterized in that: it includes a detection platform and a detection device arranged on the detection platform; the detection device includes a detection device with a It is used for the detection socket for plugging in the elevator bypass device plug, the mechanical error-proof component used to prevent the human error from identifying the elevator bypass device plug, and the electronic device used to detect whether there is a wrong line connection or short circuit inside the elevator bypass device plug. An error-proof circuit; the detection socket is arranged on the detection platform, the hole positions of the detection socket include a connection hole position and a disconnection hole position, and a mechanical error-proof component is arranged in the disconnection hole position of the detection socket; the electronic error-proof circuit Connect to the detection socket.

The elevator bypass device plug group includes normal operation plug, car door bypass plug, hall door bypass plug and rear hall door bypass plug, or normal operation plug, car door bypass plug and hall door bypass plug. In the above solution, the detection device of the present invention adopts two technical measures of mechanical error prevention and electrical error prevention, which can quickly and reliably perform effective detection on various plugs of the plug group of the elevator bypass device, so as to prevent the internal wiring of each plug from being connected incorrectly. Or plug identification errors, so as to ensure the continuous output quality of the bypass device plug group, so as to improve the safety of elevator bypass devices in elevator maintenance and inspection. The invention adopts the detection device to detect and identify some elevator bypass device plugs with poor joint wiring, and can rework these defective products in the factory, so as to avoid unnecessary trouble in the use of subsequent elevator bypass device plug groups , so that the assembly quality and correct rate of the plug group of the bypass device of the side elevator are effectively controlled.

The hole position of the detection socket is a hole position provided with a female needle seat; the mechanical error preventing component is a blocking member, and the blocking member is arranged in the female needle seat of the disconnecting hole position. The plug can be a tin-soldering seal, and through the tin-soldering seal, the electrical connection between the pin of the plug of the elevator bypass device and the female pin seat of the disconnection hole is realized, so as to prevent artificial bypassing of the elevator by means of mechanical error proofing. Device plug identified incorrectly.

The electronic error prevention circuit includes a detection switch, a power supply and an electronic error prevention unit equal to the number of detection sockets; the electronic error prevention unit, the detection socket, the detection switch and the power supply are connected through a peripheral circuit to form an electronic error prevention circuit.

Each electronic error-proofing unit includes an LED light for judging whether the inside of the plug of the elevator bypass device is wrongly connected or short-circuited, and the LED light and the connection holes in each detection socket are connected through a peripheral circuit to form an electronic error-proofing sub circuit; the LED light is arranged on the detection platform and at the side of the detection socket. The invention can detect whether there is a wrong wiring or short circuit inside the plug of the elevator bypass device through the luminous state of the LED light; when the plug of the elevator bypass device is inserted into the detection socket, the LED light illuminates, and the plug passes the electronic error-proofing circuit. , otherwise the elevator bypass device plug is detected as unqualified.

In each electronic error-proofing sub-circuit, the two connection holes connected with the elevator bypass device plug to form a loop are used as fractures; when there are two connection holes in the detection socket, the LED lights are connected in series with the fractures and pass through the peripheral Circuit connections form electronic error-proofing subcircuits.

In each electronic error-proofing sub-circuit, the two connection holes connected with the elevator bypass device plug to form a loop are used as fractures; when the number of connection holes in the detection socket is M, an LED light is connected between each two fractures. The LED light is connected in series with the fracture, and is connected through the peripheral circuit to form an electronic error-proofing sub-circuit; among them, M≥4 is an even number.

In each electronic error prevention sub-circuit, the two connection holes connected with the elevator bypass device plug to form a loop are used as fractures; when the number of connection holes in the detection socket is N, each fracture is connected with an LED light in series, and the An LED light is connected between the external connection hole and the power supply, and the LED light, the fracture and the connection holes other than the fracture are connected through the peripheral circuit to form an electronic error-proofing sub-circuit; wherein, N is an odd number and N≥5.

The detection socket includes a detection socket 1 and/or a detection socket 2; the detection socket 1 is the normal operation socket 1, the car door bypass socket 1, the hall door bypass socket 1 and the side of the rear hall door set on the detection platform. Road socket 1; the normal operation socket 1, the car door bypass socket 1, the hall door bypass socket 1 and the rear hall door bypass socket 1 each form a horizontal row and are arranged on the testing platform;

The second detection socket is the normal operation socket 2, the car door bypass socket 2 and the hall door bypass socket 2 set on the detection platform; the normal operation socket 2, the car door bypass socket 2 and the hall door bypass socket 2 Each of the two forms a row and is arranged on the detection platform.

In the present invention, each elevator bypass device socket is formed in a row and arranged on the detection platform, and is designed in a grouping form, which can facilitate the convenience and efficiency of the subsequent elevator bypass device plug group packaging and assembly. When packing and assembling, it is only necessary to bundle and assemble the elevator bypass device plugs of various types that have passed the inspection in one column, and then a single-door or double-door elevator bypass device plug group can be formed.

A method for detecting and assembling a plug group of an elevator bypass device, characterized in that: a detection socket for inserting a plug of an elevator bypass device is provided on a detection platform, and the hole positions of the detection socket include a connection hole position and a disconnection hole position;

The detection socket includes a detection socket 1 and/or a detection socket 2; the detection socket 1 is the normal operation socket 1, the car door bypass socket 1, the hall door bypass socket 1 and the side of the rear hall door set on the detection platform. Road socket 1; the normal operation socket 1, the car door bypass socket 1, the hall door bypass socket 1 and the rear hall door bypass socket 1 each form a horizontal row and are arranged on the testing platform;

The second detection socket is the normal operation socket 2, the car door bypass socket 2 and the hall door bypass socket 2 set on the detection platform; the normal operation socket 2, the car door bypass socket 2 and the hall door bypass socket 2 Two each form a row and are arranged on the detection platform;

By arranging a mechanical error-proofing component in the disconnection hole of the detection socket, a preliminary mechanical error-proofing detection method can be used to prevent human error in identifying the plug of the elevator bypass device; Check whether there is a wrong wiring or short circuit inside the elevator bypass device plug;

The elevator bypass device plugs corresponding to the normal operation socket 1, car door bypass socket 1, hall door bypass socket 1 and rear hall door bypass socket 1 that have passed the electronic error-proof circuit detection and are in the same column are grouped by grouping. Bundle and assemble to form the elevator bypass device plug group of the elevator double doors;

The elevator bypass device plugs corresponding to the normal operation socket 2, the car door bypass socket 2 and the hall door bypass socket 2 that have passed the electronic error-proofing circuit detection and are in the same column are bundled and assembled by grouping to form a single elevator door. Elevator Bypass Unit Plug Set.

In the above scheme, the present invention adopts the method of grouping to bundle and assemble various types of elevator bypass device plugs that have passed the inspection in the same column, so as to realize efficient and reliable inspection and assembly of elevator bypass device plug groups, thereby improving the efficiency of elevator bypass devices. Efficiency and correct reliability of bypass unit plug set assembly.

The mechanical error-preventing component is a blocking member arranged in the disconnection hole position, and realizes the electrical connection between the pin of the plug of the elevator bypass device and the female needle seat of the disconnection hole position through the blocking member;

The electronic error-proofing circuit includes electronic error-proofing units equal to the number of detection sockets; each electronic error-proofing unit includes an LED light for judging whether the inside of the plug of the elevator bypass device is wrongly connected or short-circuited. The connection holes in each detection socket are connected by a peripheral circuit to form an electronic error-proofing sub-circuit; the LED light is arranged on the detection platform and is located on the side of the detection socket, so as to detect whether the inside of the plug of the elevator bypass device is detected by the light-emitting state of the LED light. There is a wrong connection or short circuit; when the plug of the elevator bypass device is inserted into the detection socket, the LED light will light up, and the plug will pass the electronic error-proof circuit to pass the test, otherwise the plug of the elevator bypass device will be detected as unqualified.

The detection equipment of the elevator bypass device plug set of the present invention is used as follows: the elevator bypass device plug (normal operation plug, car door bypass plug, hall door bypass plug and rear hall door bypass plug, or normal operation plug , car door bypass plug and hall door bypass plug) are respectively inserted into the corresponding detection sockets. When the plug of the elevator bypass device cannot be inserted into the detection socket, it can be determined that the plug is a human identification error, so as to remind the operator that the plug of the elevator bypass device is wrong, so as to achieve the purpose of mechanical error prevention. When the plug of the elevator bypass device is inserted into the detection socket, it is detected whether there is a wrong wiring or short circuit inside the plug of the elevator bypass device through the lighting state of the LED light corresponding to each detection socket: if the LED light is illuminated, the plug passes through the electronic error-proof circuit. The test is qualified, otherwise the plug of the elevator bypass device is detected as unqualified.

Finally, bundle the elevator bypass device plugs corresponding to the normal operation socket 1, the car door bypass socket 1, the hall door bypass socket 1 and the rear hall door bypass socket 1 that have passed the electronic error-proof circuit detection and are in the same column. Assembled to form the elevator bypass device plug group for double doors of the elevator, which will pass the electronic error-proof circuit to detect qualified and the same column of normal operation socket 2, car door bypass socket 2 and hall door bypass socket 2 corresponding to the elevator bypass The device plugs are bundled and assembled to form an elevator bypass device plug group for a single elevator door.

Compared with the prior art, the present invention has the following advantages and beneficial effects:

1. The detection equipment for the plug group of the elevator bypass device of the present invention can quickly and reliably perform effective detection on each plug of the elevator bypass device plug group, so as to prevent the internal wiring of each plug from being connected incorrectly or the plug identification error, thereby ensuring the bypass device plug. Group continuous output quality to improve the safety of elevator bypass devices during elevator maintenance and inspection.

2. The method for detecting and assembling the plug group of the elevator bypass device of the present invention is efficient and reliable, and can improve the efficiency and correct reliability of the assembly of the elevator bypass device plug group.

Description of drawings

1 is a schematic diagram of the detection equipment of the plug group of the elevator bypass device in the first embodiment;

Fig. 2 is the electrical diagram of the detection equipment of the plug group of the elevator bypass device in the first embodiment;

Fig. 3 (a) is the schematic diagram of the normal operation plug in the first embodiment;

FIG. 3(b) is a schematic diagram of the normal operation socket 1 or the normal operation socket 2 in the first embodiment;

3(c) is a schematic diagram of an electronic error-proofing sub-circuit of the normal operation socket 1 or the normal operation socket 2 in the first embodiment;

Fig. 4 (a) is the schematic diagram of the car door bypass plug in the first embodiment;

Fig. 4 (b) is the schematic diagram of the car door bypass socket one or the car door bypass socket two in the first embodiment;

Figure 4 (c) is a schematic diagram of an electronic error-proofing sub-circuit of the first car door bypass socket or the second car door bypass socket in the first embodiment;

Fig. 5 (a) is the schematic diagram of the hall door bypass plug in embodiment one;

Fig. 5 (b) is the schematic diagram of hall door bypass socket one or hall door bypass socket two in embodiment one;

5(c) is a schematic diagram of the electronic error-proofing sub-circuit of the hall door bypass socket one or the hall door bypass socket two in the first embodiment;

Figure 6 (a) is a schematic diagram of a rear hall door bypass plug in the first embodiment;

Figure 6 (b) is a schematic diagram of a rear hall door bypass socket one in the first embodiment;

Figure 6(c) is a schematic diagram of the electronic error-proofing sub-circuit of the rear hall door bypass socket one in the first embodiment;

7 is a schematic diagram of the position of the mechanical error-proofing component in the first embodiment;

8 is a schematic diagram of the detection equipment of the plug group of the elevator bypass device in the second embodiment;

Fig. 9 is the electrical diagram of the detection equipment of the plug group of the elevator bypass device in the second embodiment;

Fig. 10 (a) is the schematic diagram of the normal operation plug in the second embodiment;

Figure 10(b) is a schematic diagram of the normal operation socket one in the second embodiment;

Figure 10 (c) is a schematic diagram of the electronic error-proofing sub-circuit of the normal operation socket one in the second embodiment;

Fig. 11 (a) is the schematic diagram of the car door bypass plug in the second embodiment;

Figure 11 (b) is a schematic diagram of the first embodiment of the car door bypass socket;

Figure 11 (c) is a schematic diagram of the electronic error-proofing sub-circuit of the car door bypass socket 1 in the second embodiment;

Figure 12 (a) is the schematic diagram of the hall door bypass plug in the second embodiment;

Figure 12 (b) is a schematic diagram of the hall door bypass socket one in the second embodiment;

Figure 12 (c) is a schematic diagram of the electronic error-proofing sub-circuit of the hall door bypass socket one in the second embodiment;

Figure 13 (a) is the schematic diagram of the rear hall door bypass plug in the second embodiment;

Figure 13(b) is a schematic diagram of the rear hall door bypass socket one in the second embodiment;

Figure 13(c) is a schematic diagram of the electronic error-proofing sub-circuit of the rear hall door bypass socket 1 in the second embodiment;

Among them, 1 is the detection platform, 2 is the detection socket, 3 is the female needle seat, 4 is the blocking piece, 5 is the detection switch, 6 is the LED light, 7 is the electronic error prevention sub-circuit, 8 is the normal operation socket 1, 9 It is the car door bypass socket 1, 10 is the hall door bypass socket 1, 11 is the rear hall door bypass socket 1, 12 is the normal operation socket 2, 13 is the car door bypass socket 2, and 14 is the hall door bypass socket Second, 15 is the fracture.

Detailed ways

The present invention will be described in further detail below with reference to the accompanying drawings and specific embodiments.

Example 1

This embodiment will be described below by taking the elevator bypass device plug group detection device of model 1 as an example.

As shown in Figures 1 to 7, the detection equipment of the elevator bypass device plug group of the present invention includes a detection platform 1 and a detection device arranged on the detection platform 1, wherein the detection device includes a plug for plugging the elevator bypass device. Detecting socket 2, a mechanical error-proofing component used to prevent human error in identifying the elevator bypass device plug, and an electronic error-proofing circuit used to detect whether there is a wrong wiring or short circuit inside the elevator bypass device plug, the detection socket 2 Set on the detection platform 1 , the holes of the detection socket 2 include connection holes and disconnection holes.

Specifically, the hole position of the detection socket 2 is the hole position where the female needle seat 3 is arranged, and the mechanical error preventing component is the blocking member 4, and the blocking member 4 is arranged in the female needle seat 3 of the disconnection hole position. The plug 4 can be a tin-soldering seal, and the tin-soldering seal is used to disconnect the pin of the elevator bypass device plug and the female pin seat 3 of the disconnection hole, so as to prevent artificial damage to the elevator by means of mechanical error proofing. Bypass unit plug identified incorrectly.

The electronic error-proofing circuit of the present invention includes a detection switch 5, a 9-volt battery as a power source and an electronic error-proofing unit equal to the number of the detection sockets 2, wherein the electronic error-proofing unit, the detection socket 2, the detection switch 5 and the power supply pass through the peripheral circuit The connections form an electronic error-proof circuit. Each electronic error-proofing unit includes an LED light 6 for judging whether the inside of the plug of the elevator bypass device is wrongly connected or short-circuited. The LED light 6 and the connection holes in each detection socket 2 are connected through the peripheral circuit to form an electronic error-proofing The sub-circuit 7 and the LED light 6 are arranged on the detection platform 1 and located on the side of the detection socket 2 . The present invention can detect whether there is a wrong circuit connection or a short circuit inside the plug of the elevator bypass device through the lighting state of the LED light 6 .

The detection socket 2 of the present invention includes a detection socket 1 and a detection socket 2. The detection socket 1 is a normal operation socket 8, a car door bypass socket 1 9, a hall door bypass socket 10 and a rear hall set on the detection platform 1. Door bypass socket one 11, the normal operation socket one 8, car door bypass socket one 9, hall door bypass socket one 10 and rear hall door bypass socket one 11 each form a row and are arranged on the testing platform 1. The invention can package and assemble the elevator bypass device plug group of elevator double doors by testing the socket-tested elevator bypass device plugs. The second detection socket is the normal operation socket 2 12 , the car door bypass socket 2 13 and the hall door bypass socket 2 14 arranged on the detection platform 1 , wherein the normal operation socket 2 12 , the car door bypass socket 2 13 and the hall door bypass socket 2 . Each of the second door bypass sockets 14 forms a row and is arranged on the detection platform 1 .

The elevator bypass device plugs in this embodiment include normal operation plugs, car door bypass plugs, hall door bypass plugs, and rear hall door bypass plugs. As shown in Figures 3(a), 3(b) and 3(c), the No. 2 pins and No. 5 pins of the normal operation plug of this embodiment need to be connected with the normal operation socket 1 8 or the normal operation socket 2 12 The No. 2 connection hole and the No. 5 connection hole are connected to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the normal operation socket 1 8 or the normal operation socket 2 12 , so as to prevent artificial identification errors of the normal operation plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the No. 2 connection hole and the No. 5 connection hole which are connected with the normal operation plug of the elevator bypass device plug to form a loop are used as the fracture 15, and the LED light 6 is connected in series with the fracture 15, and passes through the peripheral Circuit connections form electronic error-proofing subcircuits.

As shown in Figures 4(a), 4(b) and 4(c), the No. 4 pins and No. 7 pins of the car door bypass plug in this embodiment need to be connected with the car door bypass socket-9 or the car door bypass socket. If the connection holes 4 and 7 of the bypass socket 213 are connected to form a loop, the pins 3 and 6 of the car door bypass plug need to be connected with the car door bypass socket 1 9 or the car door The No. 3 connection hole and the No. 6 connection hole of the bypass socket 2 13 are connected to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the car door bypass socket 1 9 or the car door bypass socket 2 13, so as to prevent human errors from identifying the car door bypass plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the connection hole and the connecting hole that are connected to the car door bypass plug of the elevator bypass device to form a loop are used as the fracture 15, and the car door bypass socket of the electronic error-proofing sub-circuit is a 9 or the number of connection holes of the car door bypass socket 2 13 is 4, LED lights 6 are connected between each two fractures 15, LED lights 6 are connected in series with the fractures 15, and are connected by peripheral circuits to form an electronic error-proofing sub-circuit .

As shown in Figures 5(a), 5(b) and 5(c), the No. 1 pin and No. 4 pin of the hall door bypass plug in this embodiment need to be connected with the hall door bypass socket 10 or the car door The No. 1 connection hole and No. 4 connection hole of the bypass socket 2 14 are connected to form a loop, and the No. 3 pin and the No. 6 pin of the hall door bypass plug need to be connected with the hall door bypass socket one 10 or the car door. The No. 3 connection hole and the No. 6 connection hole of the bypass socket 2 14 are connected to form a loop. In this embodiment, a blocking member 4 is set at the disconnection hole of the hall door bypass socket 10 or the car door bypass socket 2 14, so as to prevent human errors from identifying the car door bypass plug by means of mechanical error prevention. In the electronic error-proofing sub-circuit, the connecting hole and the connecting hole which are connected to the hall bypass plug of the elevator bypass device to form a loop are used as the fracture 15. The hall-bypass socket of the electronic error-proofing sub-circuit 10 or the car door bypass socket 2 14 has 4 connection holes, and an LED light 6 is connected between every two fractures 15. The LED light 6 is connected in series with the fracture 15, and is connected by a peripheral circuit to form an electronic error-proofing sub-circuit .

As shown in Figures 6(a), 6(b) and 6(c), the No. 7 pins and No. 8 pins of the tailgate bypass plug in this embodiment need to be connected with the tailgate bypass socket-11 If the No. 7 connection hole and the No. 8 connection hole are connected to form a loop, the No. 3 and No. 6 pins of the rear hall door bypass plug need to be connected with the No. 3 connection hole of the rear hall door bypass socket 11 and The No. 6 connection hole is connected to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the rear hall door bypass socket 11, so as to prevent human error from identifying the car door bypass plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the connection holes and the connecting holes which are connected with the tailgate bypass plug of the elevator bypass device plug to form a loop are used as the fracture 15, and the tailgate bypass of the electronic error-proofing sub-circuit The number of connection holes of the socket 11 is 4, and an LED light 6 is connected between every two fractures 15. The LED light 6 is connected in series with the fractures 15, and is connected by a peripheral circuit to form an electronic error-proofing sub-circuit.

The method for detecting and assembling the plug group of the elevator bypass device of the present invention is as follows: by arranging a mechanical error-proofing component in the disconnection hole position of the detection socket 2, a preliminary mechanical error-proofing detection method can be used to prevent artificial interference on the plug of the elevator bypass device. By connecting the electronic error-proof circuit to the detection socket 2, the subsequent detection of whether there is a wrong line connection or short-circuit inside the plug of the elevator bypass device is realized.

The elevators corresponding to the normal running socket 8, the car door bypass socket 9, the hall door bypass socket 10 and the rear hall door bypass socket 11 which are qualified and in the same column are detected by the grouping method. The bypass device plugs are bundled and assembled to form an elevator bypass device plug group for double elevator doors;

The elevator bypass device plugs corresponding to the normal operation socket 2 12 , the car door bypass socket 2 13 and the hall door bypass socket 2 14 that have passed the electronic error-proofing circuit detection and are in the same column are bundled and assembled in a grouping manner to form Elevator bypass unit plug set for elevator single door.

The invention adopts the method of grouping to bundle and assemble the elevator bypass device plugs that have passed the inspection of various types in the same column, so as to realize efficient and reliable inspection and assembly of the elevator bypass device plug group, thereby improving the elevator bypass device plug group. Efficiency and correct reliability of assembly.

In the detection and assembling method of the present invention, the mechanical error-proofing component is the blocking member 4 arranged in the disconnection hole position, and the plug pin of the plug of the elevator bypass device and the female connector of the disconnection hole position can be disconnected through the blocking member 4. The needle seat 3 is electrically connected. The electronic error-proofing circuit includes electronic error-proofing units equal to the number of detection sockets, and each electronic error-proofing unit includes an LED light 6 for judging whether the inside of the plug of the elevator bypass device is wrongly connected or short-circuited. The LED light 6 and The connection holes in each detection socket 2 are connected by peripheral circuits to form an electronic error-proofing sub-circuit. The LED lamp 6 is arranged on the detection platform 1 and is located on the side of the detection socket 2, so as to detect whether there is a wrong wiring or short circuit inside the plug of the elevator bypass device through the lighting state of the LED lamp 6; After the socket 2, the LED light 6 lights up, then the plug is qualified by the electronic error-proof circuit detection, otherwise the elevator bypass device plug is detected as unqualified.

The detection equipment of the elevator bypass device plug set of the present invention is used as follows: the elevator bypass device plug (normal operation plug, car door bypass plug, hall door bypass plug and rear hall door bypass plug, or normal operation plug , car door bypass plug and hall door bypass plug) are respectively inserted into the corresponding detection socket 2. When the plug of the elevator bypass device cannot be inserted into the detection socket 2, it can be determined that the plug is a human identification error, so as to remind the operator that the plug of the elevator bypass device is wrong, so as to achieve the purpose of mechanical error prevention. When the plug of the elevator bypass device is inserted into the detection socket, it is detected whether there is a wrong wiring or short-circuit inside the plug of the elevator bypass device through the lighting state of the LED light 6 corresponding to each detection socket 2: the LED light 6 is illuminated, then the plug passes the electronic The error-proofing circuit has passed the test, otherwise the plug of the elevator bypass device is unqualified.

Finally, the elevator bypasses corresponding to the normal operation socket 8, the car door bypass socket 9, the hall door bypass socket 10 and the rear hall door bypass socket 11, which are qualified and in the same column, are detected by the electronic error-proof circuit. The device plugs are bundled and assembled to form a double-door elevator bypass device plug group, which will pass the electronic error-proof circuit detection and pass the normal operation socket 2 12, car door bypass socket 2 13 and hall door bypass socket in the same column. The elevator bypass device plugs corresponding to 2 14 are bundled and assembled to form an elevator bypass device plug group for a single elevator door.

Embodiment 2

This embodiment is described below by taking the elevator bypass device plug group detection device of type 2 as an example.

The only difference between this embodiment and the first embodiment is that the electronic error prevention sub-circuits of this embodiment are different.

As shown in Figures 8 to 13(c), the detection equipment of the elevator bypass device plug group of this embodiment includes a detection platform 1 and a detection device arranged on the detection platform 1, wherein the detection device includes a detection device for plugging the elevator bypass device 2. A mechanical error-proofing component used to prevent people from misidentifying the elevator bypass device plug and an electronic error-proofing circuit used to detect whether there is a wrong wiring or short circuit inside the elevator bypass device plug, The detection socket 2 is arranged on the detection platform 1. The holes of the detection socket 2 include a connection hole and a disconnection hole. The mechanical error-proofing component is arranged in the disconnection hole of the detection socket 2. Socket 2 is connected.

The electronic error-proofing circuit of the present invention includes a detection switch 5, a 9-volt battery as a power source and an electronic error-proofing unit equal to the number of the detection sockets 2, wherein the electronic error-proofing unit, the detection socket 2, the detection switch 5 and the power supply pass through the peripheral circuit The connections form an electronic error-proof circuit. Each electronic error-proofing unit includes an LED light 6 for judging whether the inside of the plug of the elevator bypass device is wrongly connected or short-circuited. The LED light 6 and the connection holes in each detection socket 2 are connected through the peripheral circuit to form an electronic error-proofing The sub-circuit 7 and the LED light 6 are arranged on the detection platform 1 and located on the side of the detection socket 2 . The present invention can detect whether there is a wrong circuit connection or a short circuit inside the plug of the elevator bypass device through the lighting state of the LED light 6 .

The detection socket 2 of the present invention includes a detection socket 1, and the detection socket 1 is a normal operation socket 8, a car door bypass socket 1 9, a hall door bypass socket 10 and a rear hall door bypass socket set on the detection platform 1. One 11, the normal operation socket one 8, the car door bypass socket one 9, the hall door bypass socket one 10 and the rear hall door bypass socket one 11 each form a row and are arranged on the detection platform 1. According to the invention, the elevator bypass device plugs that are qualified after the normal operation socket 8, the car door bypass socket 9, the hall door bypass socket 10 and the rear hall door bypass socket 11 can be packaged and assembled to form an elevator with double doors. Bypass device plug group, through the normal operation socket-8, car door bypass socket-9 and hall door bypass socket-10 qualified elevator bypass device plugs can be packaged and assembled to form a single-door elevator bypass device plug group .

The elevator bypass device plugs in this embodiment include normal operation plugs, car door bypass plugs, hall door bypass plugs, and rear hall door bypass plugs. As shown in Figures 10(a), 10(b) and 10(c), the No. 2 and No. 5 pins of the normal operation plug of this embodiment are required to be connected with the No. 2 connection holes and the No. 2 connection holes of the normal operation socket-8. If the No. 5 connection hole is connected to form a loop, the pin 4 and pin 9 of the car door bypass plug need to be connected with the No. 4 connection hole and the No. 9 connection hole of the normal operation socket-8 to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the normal operation socket 1 8, so as to prevent human error from identifying the car door bypass plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the connection holes and the connecting holes which are connected with the normal operation plug of the elevator bypass device plug to form a loop are used as fractures 15, and the connection holes of the normal operation socket-8 of the electronic error-proofing sub-circuit The number of bits is 4, and an LED lamp 6 is connected between every two fractures 15. The LED lamp 6 is connected in series with the fractures 15, and is connected through a peripheral circuit to form an electronic error-proofing sub-circuit.

As shown in Figures 11(a), 11(b) and 11(c), the No. 3 pins and No. 6 pins of the car door bypass plug in this embodiment are the No. 3 pins that need to be connected with the car door bypass socket-9 If the connection hole and the No. 6 connection hole are connected to form a loop, the No. 4 pin, No. 7 pin and No. 9 pin of the car door bypass plug need to be connected with the No. 4 connection hole of the car door bypass socket-9. , No. 7 connection holes and No. 9 connection holes are connected to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the car door bypass socket 1 9, so as to prevent human errors from identifying the car door bypass plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the connection hole and the connecting hole that are connected to the car door bypass plug of the elevator bypass device to form a loop are used as the fracture 15, and the car door bypass socket of the electronic error-proofing sub-circuit is a The number of connection holes of 9 is 5, and each fracture 15 is connected in series with an LED light 6. The connection hole 9 outside the fracture 15 and the power supply are connected with an LED light 6. The LED light 6, the fracture 15 and the fracture 15 The external connection holes 9 are connected through the peripheral circuit to form an electronic error-proofing sub-circuit.

As shown in Figures 12(a), 12(b) and 12(c), the No. 3 pins and No. 6 pins of the hall bypass plug in this embodiment are the No. 3 pins that need to be connected with the hall bypass socket-10 If the connection hole and the No. 6 connection hole are connected to form a loop, the No. 4 pin, No. 1 pin and No. 9 pin of the hall door bypass plug need to be connected with the No. 4 connection hole of the hall door bypass socket 10 , No. 1 connection hole and No. 9 connection hole are connected to form a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the hall door bypass socket 10, so as to prevent human error in identifying the car door bypass plug by means of mechanical error prevention. In the electronic error-proofing sub-circuit, the connecting hole and the connecting hole which are connected to the hall bypass plug of the elevator bypass device to form a loop are used as the fracture 15. The hall-bypass socket of the electronic error-proofing sub-circuit The number of connection holes of 10 is 5, and each fracture 15 is connected in series with an LED light 6, and the connection hole 9 outside the fracture 15 is connected with the power supply. The external connection holes 9 are connected through the peripheral circuit to form an electronic error-proofing sub-circuit.

As shown in Figures 13(a), 13(b) and 13(c), pins 3 and 6 of the tailgate bypass plug in this embodiment need to be connected with the tailgate bypass socket 11 If the No. 3 connection hole and the No. 6 connection hole are connected to form a loop, the No. 7 and No. 8 pins of the rear hall door bypass plug need to be connected with the No. 7 connection hole of the rear hall door bypass socket-11 and If the No. 8 connection hole is connected to form a loop, the No. 4 and 9 pins of the rear hall door bypass plug need to be connected with the No. 4 connection hole and the No. 9 connection hole of the rear hall door bypass socket 11. forming a loop. In this embodiment, a blocking member 4 is provided at the disconnection hole position of the rear hall door bypass socket 1 1 , so as to prevent human error from identifying the rear hall door bypass plug by means of mechanical error prevention. In this electronic error-proofing sub-circuit, the connection holes and the connecting holes which are connected with the tailgate bypass plug of the elevator bypass device plug to form a loop are used as the fracture 15, and the tailgate bypass of the electronic error-proofing sub-circuit The number of connection holes of the socket 11 is 6, and an LED light 6 is connected between every two fractures 15. The LED light 6 is connected in series with the fractures 15, and is connected by a peripheral circuit to form an electronic error-proofing sub-circuit.

The method for detecting and assembling the plug group of the elevator bypass device of the present invention is as follows: by arranging a mechanical error-proofing component in the disconnection hole position of the detection socket 2, a preliminary mechanical error-proofing detection method can be used to prevent artificial interference on the plug of the elevator bypass device. By connecting the electronic error-proof circuit to the detection socket 2, the subsequent detection of whether there is a wrong line connection or short-circuit inside the plug of the elevator bypass device is realized.

The elevators corresponding to the normal running socket 8, the car door bypass socket 9, the hall door bypass socket 10 and the rear hall door bypass socket 11 which are qualified and in the same column are detected by the grouping method. The bypass device plugs are bundled and assembled to form a double-door elevator bypass device plug group; the normal operation socket 8 and the car door bypass socket 9 that have passed the electronic error-proof circuit detection and are qualified in the same column are grouped into groups. The elevator bypass device plugs corresponding to the hall door bypass socket 10 are bundled and assembled to form an elevator bypass device plug group for a single elevator door. The invention adopts the method of grouping to bundle and assemble the elevator bypass device plugs that have passed the inspection of various types in the same column, so as to realize efficient and reliable inspection and assembly of the elevator bypass device plug group, thereby improving the elevator bypass device plug group. Efficiency and correct reliability of assembly.

Other structures of this embodiment are the same as those of the first embodiment.

The above-mentioned embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above-mentioned embodiments, and any other changes, modifications, substitutions, combinations, The simplification should be equivalent replacement manners, which are all included in the protection scope of the present invention.

Claims (10)

1. A detection device of a plug group of an elevator bypass device is characterized in that: comprises a detection platform and a detection device arranged on the detection platform; the detection device comprises a detection socket for plugging a plug of the elevator bypass device, a mechanical error-proofing component for preventing the elevator bypass device plug from being identified by mistake manually, and an electronic error-proofing circuit for detecting whether a line error connection or short circuit phenomenon exists in the elevator bypass device plug; the detection socket is arranged on the detection platform, the hole sites of the detection socket comprise a connection hole site and a disconnection hole site, and the mechanical error-proofing component is arranged in the disconnection hole site of the detection socket; the electronic mistake-proofing circuit is connected with the detection socket.

2. The elevator bypass device plug set detection apparatus of claim 1, wherein: the hole site of the detection socket is a hole site provided with a female needle seat; the mechanical error-proofing component is a plugging piece which is arranged in the female needle seat of the disconnection hole site.

3. The elevator bypass device plug set detection apparatus of claim 1, wherein: the electronic error-proofing circuit comprises detection switches, a power supply and electronic error-proofing units with the number equal to that of the detection sockets; the electronic error-proofing unit, the detection socket, the detection switch and the power supply are connected through a peripheral circuit to form an electronic error-proofing circuit.

4. The elevator bypass device plug set detection apparatus of claim 3, wherein: each electronic error-proofing unit comprises an LED lamp used for judging whether a line inside a plug of the elevator bypass device is connected in a wrong way or in a short circuit, and the LED lamp and a connecting hole in each detection socket are connected through a peripheral circuit to form an electronic error-proofing sub-circuit; the LED lamp is arranged on the detection platform and is positioned on the side edge of the detection socket.

5. The elevator bypass device plug set detection apparatus of claim 4, wherein: in each electronic error-proofing sub-circuit, two connecting hole sites which are connected with a plug of the elevator bypass device to form a loop are used as fractures; when two connecting hole sites are arranged in the detection socket, the LED lamp is connected with the fracture in series and connected through a peripheral circuit to form an electronic mistake-proofing sub-circuit.

6. The elevator bypass device plug set detection apparatus of claim 4, wherein: in each electronic error-proofing sub-circuit, two connecting hole sites which are connected with a plug of the elevator bypass device to form a loop are used as fractures; when the number of the connecting hole sites in the socket is detected to be M, an LED lamp is connected between every two fractures, and the LED lamps are connected with the fractures in series and connected through a peripheral circuit to form an electronic mistake proofing sub-circuit; wherein M is more than or equal to 4 and is an even number.

7. The elevator bypass device plug set detection apparatus of claim 4, wherein: in each electronic error-proofing sub-circuit, two connecting hole sites which are connected with a plug of the elevator bypass device to form a loop are used as fractures; when the number of the connecting hole sites in the socket is detected to be N, each fracture is connected with an LED lamp in series, the connecting hole sites outside the fractures and a power supply are connected with the LED lamps, and the LED lamps, the fractures and the connecting hole sites outside the fractures are connected through peripheral circuits to form an electronic anti-error sub-circuit; wherein N is an odd number and N is not less than 5.

8. The elevator bypass device plug set detection apparatus of claim 1, wherein: the detection socket comprises a first detection socket and/or a second detection socket; the detection socket I is a normal operation socket I, a car door bypass socket I, a hall door bypass socket I and a backroom door bypass socket I which are arranged on the detection platform; the normal operation socket I, the car door bypass socket I, the hall door bypass socket I and the backroom door bypass socket I respectively form a transverse row and are arranged on the detection platform;

the second detection socket is a second normal operation socket, a second car door bypass socket and a second hall door bypass socket which are arranged on the detection platform; and the second normal operation socket, the second car door bypass socket and the second hall door bypass socket form a transverse row and are arranged on the detection platform.

9. A detection assembly method for a plug group of an elevator bypass device is characterized by comprising the following steps: a detection socket for plugging a plug of the elevator bypass device is arranged on the detection platform, and hole sites of the detection socket comprise a connection hole site and a disconnection hole site;

the detection socket comprises a first detection socket and/or a second detection socket; the detection socket I is a normal operation socket I, a car door bypass socket I, a hall door bypass socket I and a backroom door bypass socket I which are arranged on the detection platform; the normal operation socket I, the car door bypass socket I, the hall door bypass socket I and the backroom door bypass socket I respectively form a transverse row and are arranged on the detection platform;

the second detection socket is a second normal operation socket, a second car door bypass socket and a second hall door bypass socket which are arranged on the detection platform; the normal operation socket II, the car door bypass socket II and the hall door bypass socket II form a transverse row respectively and are arranged on the detection platform;

the mechanical error-proofing component is arranged in the disconnection hole position of the detection socket, so that the problem that the plug of the elevator bypass device is identified by people in an artificial way in a mechanical error-proofing detection mode is solved; the detection socket is connected with an electronic error-proofing circuit, so that whether a line is connected in a wrong way or in a short circuit exists in the plug of the elevator bypass device or not is detected subsequently;

the elevator bypass device plugs corresponding to the first normal operation socket, the first car door bypass socket, the first hall door bypass socket and the first backroom door bypass socket which are qualified through electronic error-proofing circuit detection and are arranged in the same column are bundled and assembled in a grouping mode to form an elevator bypass device plug group with double doors;

and the elevator bypass device plugs corresponding to the normal operation socket II, the car door bypass socket II and the hall door bypass socket II which are qualified through the detection of the electronic error-proofing circuit and are arranged in the same column are bundled and assembled in a grouping mode to form an elevator bypass device plug group with a single elevator door.

10. The method of claim 9, wherein the method further comprises the steps of: the mechanical error-proofing component is a plugging piece arranged in the disconnection hole site, so that the contact pin of the elevator bypass device plug is disconnected from the female pin seat of the disconnection hole site through the plugging piece;

the electronic error-proofing circuit comprises electronic error-proofing units with the number equal to that of the detection sockets; each electronic error-proofing unit comprises an LED lamp used for judging whether a line inside a plug of the elevator bypass device is connected in a wrong way or in a short circuit, and the LED lamp and a connecting hole in each detection socket are connected through a peripheral circuit to form an electronic error-proofing sub-circuit; the LED lamp is arranged on the detection platform and positioned on the side edge of the detection socket, so that whether a line is connected in a wrong way or in a short circuit in the plug of the elevator bypass device is detected through the luminous state of the LED lamp; after the plug of the elevator bypass device is plugged into the detection socket, the LED lamp emits light, the plug is detected to be qualified through the electronic mistake-proofing circuit, and otherwise the plug of the elevator bypass device is detected to be unqualified.

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