DE202017002489U1 - System for measuring a safety distance between the steps and edges of an escalator and for locating hidden dangers - Google Patents

Abstract

A system for measuring a safety distance between escalator steps and sidewalks and for locating hidden hazards, the system comprising: a distance measuring subsystem communicating with a terminal, the distance measuring subsystem being used to measure a walking distance of the steps in real time and for transmitting the measured distance data information to the terminal for processing; a gap measuring subsystem, wherein the gap measuring subsystem is used to detect in real time the changes in the gap between the steps and sidebars and to transmit the gap data information to the terminal for processing; and a terminal, wherein the terminal is used for receiving the data information of the distance measuring subsystem and the gap measuring subsystem for processing and display.

Description

Technical field of utility model

The present utility model relates to an escalator or passenger conveyor, and more particularly to a system for measuring a safety distance between the steps and skirting of an escalator and for locating hidden dangers.

Background of the utility model

When operating an escalator, excessive clearance between the steps and the two-sided skirting tend to pinch foreign objects or children's fingers and toes, resulting in injured body parts or a damaged escalator. In the past, children's fingers, toes, or rubber boots have often become trapped in the space between the moving steps and skirting, causing injuries. Checking and regular maintenance of the escalator as part of a safety check must also cover the distance between the steps and skirting boards, which should not exceed 4 mm on one side in accordance with national safety standards, with the sum of the distances on both sides not being should be more than 7 mm.

At present, detection and measurement of the clearance between the steps and skirters is generally performed manually using a distance gauge or a straight steel ruler after the escalator has moved to its rest position because there are no professional equipment for detection, mainly for the following Problems: Firstly, there is a difference between the recorded results at resting levels and at operating levels (due to the shaking of the steps when the escalator is in operation caused by wear of the guide rails and rollers); Secondly, it is inefficient to perform a manual measurement with a steel ruler (distance gauge), making it difficult to measure all distances so that some hidden dangers can easily be overlooked; Third, readings are easily affected by the low resolution or measurement accuracy of the straight steel ruler and the gap gauge, as well as by large errors in reading by the service personnel, especially when a reading is near a critical value.

Summary of the utility model

To solve the above drawbacks in the prior art, the present utility model provides a system of high accuracy and high efficiency for measuring a safety clearance between the steps and ledges of an escalator, and for locating hidden dangers.

Therefore, the technical solution provided by the present utility model with respect to these problems is as follows:
A system for measuring a safety distance between steps and ledges of an escalator and for locating hidden hazards, the system comprising a terminal and a distance measuring subsystem and a gap measuring subsystem communicating with the terminal;
wherein the distance measuring subsystem is used to measure a running distance of the stages in real time and to transmit the measured distance data information to the terminal for processing;
wherein the gap measuring subsystem is used to detect changes in the gap between the steps and margins in real time and to transfer the gap data information to the terminal for processing; and
wherein the terminal is used for receiving the above data information of the distance measuring subsystem and the gap measuring subsystem for a processing and a display.

As a further refinement of the technical solution, the distance measuring subsystem comprises a distance measuring device and an integrated distance computer processing module (also referred to as a lower level processing module for the distance).

As a further improvement of the technical solution, the distance measuring device comprises a rubber wheel and a rotary encoder, which is connected to the rubber wheel via a coupling, wherein the distance measuring device is mounted on a horizontal segment of the edge of the escalator via a scaffold with a suction disc.

As a further refinement of the technical solution, the integrated distance computer processing module comprises a microprocessor CPU, which is respectively connected to a data memory and a wireless communication circuit, wherein an input end of the microprocessor CPU is connected to a charging and power supply circuit and a step run distance measuring circuit, the charging and Power supply circuit is connected to a rechargeable lithium battery, wherein an input end of the step run distance measuring circuit is connected to a pulse shaping circuit, and the integrated distance computer processing module communicates with the terminal via the wireless communication circuit.

As a further refinement of the technical solution, the gap measuring subsystem comprises a sensor base, a sensor mounted on the sensor base, and an integrated gap computer processing module (also referred to as a lower level gap processing module).

As a further improvement of the technical solution, the sensor is a contact type displacement sensor.

As a further improvement of the technical solution, the sensor base includes a clamp base and a clamp plate hooked to an upper end of the clamp base, the clamp base provided with a first through hole and the clamp plate provided with a second through hole at a position corresponding to the first through hole in the clamp base; wherein the clamping base is connected to the clamping plate via a fastener that passes through both the first through hole and the second through hole, and wherein the lower ends of the clamping base and the clamping plate are inserted at the same time in tooth slots of an escalator foot plate.

As a further improvement of the technical solution, the integrated gap computer processing module comprises a microprocessor CPU, each connected to a data memory and a wireless communication circuit, wherein an input end of the microprocessor CPU is connected to a charge and power supply circuit and an A / D converter wherein the charging and power supply circuit is connected to the rechargeable lithium battery, wherein an input end of the A / D converter is connected to a signal conversion circuit, and wherein the embedded interworking computer processing module communicates with the terminal via the wireless communication circuit.

The present utility model has the following advantages: The system for measuring a safety distance between the steps and skirting boards of an escalator and for locating hidden hazards according to the present utility model improves the work of the maintenance personnel and reduces the workload; the system of the present utility model is of high accuracy and eliminates the reading errors caused by manual reading, thereby assisting the maintenance personnel in fully detecting the hidden dangers so as to minimize escalator accidents caused by such hidden dangers; and its function of accurately locating hidden hazards may assist maintenance personnel to speed up the maintenance and adjustment work. Therefore, the present utility model has great importance for the safe operation of the escalator and for the safety of the users, and plays a positive role in advancing the overall quality assurance.

Brief description of the drawings

The present application is further explained below together with the drawings and specific embodiments, wherein:

1 a structural representation of the present utility model is;

2 Fig. 10 is a functional block diagram of an integrated gap measuring computer processing module of the present utility model;

3 Fig. 10 is a functional block diagram of an integrated distance measuring computer processing module of the present utility model;

4 Fig. 10 is a display illustration of the measurement of the present utility model;

5 Fig. 12 is a structural diagram of a sensor base of the present utility model;

6 Fig. 12 is a structural diagram of a clamp base of the present utility model;

7 Fig. 3 is a structural diagram of a clamping plate of the present utility model; and

8th Fig. 3 is a structural view of a fastener of the present utility model.

Detailed description of the embodiments

Regarding 1 includes a system for measuring a safety distance between the escalator steps and ledges, and a terminal for locating hidden hazards 1 and a gap measuring subsystem 2 and a distance measuring subsystem 3 which communicate with the terminal;
wherein the distance measuring subsystem 3 is used to measure a running distance of the steps in real time and to transmit the measured distance data information to the terminal for processing;
the space-measuring subsystem 2 is used to detect changes in the gap between the steps and the sidebars in real time and to transfer the gap data information to the terminal for processing; and
the terminal 1 is used to receive the above data information of the distance measuring subsystem and the gap measuring subsystem for processing and display.

The distance measuring subsystem 3 includes a distance measuring device 32 and an integrated distance computer processing module 31 ,

Further with reference to 3 includes the distance measuring device 32 a rubber wheel 323 and a rotary encoder 322 , which is connected via a coupling and on a horizontal segment of the skirting of the escalator via a scaffold 321 is attached with a suction disc. The Embedded Distance Computer Editing Module 31 comprises a microprocessor CPU, each connected to a data memory and a wireless communication circuit, wherein an input end of the microprocessor CPU is connected to a charging and power supply circuit and a step-distance measuring circuit, wherein the charging and power supply circuit with a rechargeable lithium battery wherein an input end of the step track distance measuring circuit is connected to a pulse shaping circuit, and wherein the integrated distance computer processing module communicates with the terminal via the wireless communication circuit 1 communicated.

The gap measuring subsystem 2 includes a sensor base 22 , a sensor 23 on the sensor base 22 is attached, and an integrated space computer processing module 21 , The sensor 23 includes a contact type displacement sensor. The sensor base 22 includes a clamp base 221 and a clamping plate 223 at an upper end of the clamp base 221 is hooked, with the clamp base 221 is provided with a first through hole, and wherein the clamping plate 223 with a second through hole at a position corresponding to the first through hole in the clamp base 221 is provided, the clamping base 221 with the clamping plate 223 by a fastener 222 which passes through both the first through hole and the second through hole, and lower ends of the clamp base 221 and the clamping plate 223 are inserted at the same time in the tooth slots of an escalator footplate.

Regarding 6 includes the clamp base 221 a reference surface 2213 parallel to the escalator footplate, positioning surfaces 2211 which are vertically down at the front and back sides of the reference surface 2213 are arranged, a clamping surface 2212 which is vertically down to the right side of the reference surface 2213 is arranged, an auxiliary surface 2214 which is vertically up to the left side of the reference surface 2213 is arranged, and an installation surface 2215 which is parallel to the reference surface and vertical to the auxiliary surface, and wherein the first through hole 2216 in the auxiliary surface 2214 is arranged. Continue with reference to 7 includes the clamping plate 223 a clamping surface 2231 and connecting hooks 2232 , which are vertically upwardly connected to the left side of the clamping surface, wherein the clamping surface 2231 parallel to the auxiliary surface 2214 the clamp base 221 is, the installation surface 2215 is provided with two openings, wherein the connecting hooks 2232 for hooking to the installation surface 2215 pass through the two openings, and wherein the second through hole 2233 on the clamping surface 2231 is arranged. 8th is a structural representation of the fastener. The fastener 222 includes a cam-like clamping lever 32 and a screwed onto the clamping lever nut 2221 , where the clamping lever 2222 through the first through hole 2216 and the second through hole 2233 goes through it. In operation, the connection hooks 2232 the clamping plate 223 with the two openings in the installation surface 2215 the clamp base 221 connected. A suitable position is selected on a step foot plate of the escalator or passenger conveyor, with an adjustment of the position of the clamping plate 223 is performed to the clamping surface 2231 the clamping plate 223 and the clamping surface 2212 the clamp base 221 to insert into the tooth slots of the escalator foot plate, in which case the positioning surface 2211 is fixedly connected to the step foot plate to provide a positioning function. The cam-type clamping lever 2222 of the fastener 222 passes through the through holes in the clamping plate 223 and the auxiliary surface 2214 the clamp base 221 , where the mother 2221 on the cam-like clamping lever 2222 is attached and rotated to temporarily clamp the device to the step foot plate. Finally, a handle on the cam-like clamping lever 2222 pivoted to secure the base securely on the step foot plate, then the sensor used for the detection to perform inspection tests on the reference surface 2213 is attached.

Further with reference to 2 includes the included gap computer processing module 21 a microprocessor CPU connected respectively to the data memory and the wireless communication circuit, wherein an input end of the microprocessor CPU is connected to the charging and power supply circuit and an A / D converter, the charging and power supply circuit being connected to the rechargeable lithium battery wherein an input end of the A / D converter is connected to a signal conversion circuit, and wherein the integrated space computer processing module communicates with the terminal via the wireless communication circuit.

If the gap measuring subsystem 2 For detecting the change in the gap between the steps and the skirting, two markings are made with a marker pin at skirting positions symmetrical left and right, respectively at the beginning of the escalator (as a zero moving position of the sensor) wherein the gaps between the steps and the edge ledges of the escalator are measured at the two marked positions using a rectilinear ruler or a distance gauge. The displacement sensor 23 is firmly on the sensor mounting base 22 attached, with the clamp base 221 and the clamping plate 223 the sensor attachment base 22 be adjusted to ensure that the moving ends of the displacement sensors 23 coincide on both sides with the two markings, wherein the fastener 222 is rotated to the displacement sensor 23 firmly on the step foot plate of the escalator. The built-in gap computer editing module 21 , which is placed on the step foot plate, is an embedded system which is powered by the lithium battery, occupies a processor core of the CPU, and is internally provided with the signal conversion circuit. The of the displacement sensor 23 transmitted resistance signals are converted by the signal conversion circuit into voltage signals, wherein a high resolution A / D conversion is performed under the control of the CPU, which calculates and derives a precise amount of change of the gap, the amount of change then via the wireless communication circuit in real time to the terminal 1 is sent.

If the distance measuring subsystem 3 is installed in real time to monitor the step running distance, then the rubber wheel 323 on an axis with the rotary encoder 322 connected, the scaffolding 321 is fixed to the skirting on a horizontal segment of the escalator, and a pivoting arm of the scaffold 321 is adjusted so that the rubber wheel 323 of the sensor presses firmly on the steps at the horizontal segment of the escalator. The rubber wheel 323 , which is in direct contact with the escalator, is preferably a wheel made of abrasion-resistant rubber and coaxial by an elastic coupling, ie on an axis with the rotary encoder 323 connected. when the rubber wheel 323 turns with the escalator, then turns the rotary encoder 322 synchronous and generates pulse signals. The Embedded Distance Computer Editing Module is as in 3 is disposed outside the stages, and is also an embedded system powered by the lithium battery, which occupies a processor core of the CPU and is internally provided with the pulse shaping circuit. The pulse shaping circuit performs shaping and filtering on the pulse signals sent out by the rotary encoder, and then sends the pulse signals for calculation to the step speed and track distance measuring circuit so as to determine the accurate step speed and running distance, which then via the wireless communication circuit in real time under the control of the CPU to the terminal 1 be sent.

After installation, the system will be activated. Power switch on the terminal 1 , the integrated space computer editing module 21 and the embedded distance computer processing module 31 are turned on. A test software of the terminal 1 is started and the system is activated to perform a communication acquisition; and if the communication is "good", the process proceeds to the next step. A setting of parameters is made on the test software of the terminal 1 wherein the ID number of the escalator to be detected, corresponding data information to be acquired, and the space value at the initial position for the measurement are input to the system. The escalator is put into operation at a maintenance speed, with the rubber wheel 323 of the distance measuring subsystem 3 moved along with the stages, the rotary encoder 322 Pulse signals generated, wherein the pulse shaping circuit to that of the rotary encoder 322 emitted pulse signals, a shaping and filtering and then sends the pulse signals for a calculation to the step speed and distance measuring circuit, so as to determine the exact step speed and the running distance, which to the gap measuring subsystem 2 and the terminal 1 via the wireless communication circuit in real time under the control sent to the CPU. After receiving the signals from the distance measuring subsystem 3 converts the gap measuring subsystem 2 the resistance signals from the displacement sensor 23 into voltage signals, performs high-resolution A / D conversion under the control of the CPU, which derives a precise amount of change of the space by calculation, and transmits the amount of change to the terminal in real time via the wireless communication circuit 1 , The terminal 1 takes the data information of the gap measuring subsystem 2 and the distance measuring subsystem 3 in real time, adds the gap change amount to the initial value of the gap to obtain a gap value of a real time position, and processes the gap value and the distance. As in 4 is shown, the horizontal axis represents that of the distance measuring subsystem 3 distance signals obtained while the vertical axis represents the space value signals. Three curves represent the spaces between the escalator steps and the sidebars on both sides, with the sum of the spaces at each symmetrical left and right positions being plotted and stored as data files, respectively. If the gap between the steps and the sidebar on one side exceeds 4 mm, or the sum of the clearances at the opposite symmetrical left and right positions exceeds 7 mm, then the curves will be rendered in red, allowing the location of hidden hazards , If the gap measuring subsystem 2 reaches the other end (the escalator, ie the "exit"), then the escalator stops running and the test ends, with the curve and data files being stored by the test software. Hidden threats can be detected and located by those in the terminal 1 stored images and data are checked so that the manufacturer is supported in a readjustment.

• 1) Vorbereitung einer Messung;
• a) Markieren einer Anfangsposition: eine Markierung wird mit einem Markierungsstift an Positionen vorgenommen, die links und rechts symmetrisch an den Randleisten sind, und zwar jeweils am Beginn der Rolltreppe, das heißt, bei einer Null-Bewegung-Position des Sensors, wobei der Zwischenraumwert zwischen den Stufen und den Randleisten der Rolltreppe an den zwei markierten Positionen unter Verwendung eines geradlinigen Lineals oder einer Abstandslehre als die Anfangswerte des Zwischenraumes gemessen werden;
• b) Installation des Zwischenraum-Mess-Subsystems: Der Verschiebungssensor wird auf der Sensorbefestigungsbasis angebracht und fixiert, wobei die Klemmbasis und die Klemmplatte der Sensorbefestigungsbasis so eingestellt werden, um sicherzustellen, dass die Verschiebungssensoren auf beiden Seiten mit den zwei in Schritt a) vorgenommenen Markierungen zusammenfallen bzw. übereinstimmen, wobei das Befestigungselement gedreht wird, um den Verschiebungssensor auf der Stufen-Fußplatte der Rolltreppe anzubringen und zu fixieren;
• c) Installation des Abstandsmess-Subsystem: Die Abstandsmess-Einrichtung wird auf der Rolltreppe durch die Saugscheibe des Gerüsts fixiert, wobei der Schwenkarm des Gerüsts so eingestellt wird, um zu ermöglichen, dass das Gummirad fest auf das horizontale Segment der Stufen der Rolltreppe drückt;
• d) System-Startup: Die Netzschalter am Endgerät, das eingebundene Zwischenraum-Computerbearbeitungsmodul und das eingebundene Abstands-Computerbearbeitungsmodul werden eingeschaltet, und es wird eine Endgerät-Testsoftware gestartet, um eine Kommunikationserfassung auszuführen; und falls die Kommunikation gut ist, schreitet das Verfahren zum nächsten Schritt über;
• e) Einstellen von Grund-Informationen: Die ID-Nummer der zu erfassenden Rolltreppe und entsprechende zu erfassende Dateninformationen werden unter einer Parameter-Einstell-Option eingegeben; und
• f) Einstellen von Anfangswerten: Die in Schritt a) gemessenen Anfangs-Zwischenraumwerte werden in das System eingegeben.
• 2) Die Rolltreppe wird mit einer Wartungs-Geschwindigkeit gefahren, wobei sich das Gummirad des Abstandsmess-Subsystems entlang der Stufen bewegt, wobei der Drehkodierer Pulssignale erzeugt, wobei der Pulsformungsschaltkreis an den von dem Drehkodierer übertragenen Pulssignalen eine Formung und Entstörung durchführt und die Pulssignale dann für eine Berechnung an den Stufen-Laufabstand-Messschaltkreis sendet, um so die Stufen-Laufgeschwindigkeit und den Abstand herzuleiten, welche über den Drahtloskommunikationsschaltkreis in Echtzeit unter der Steuerung der Mikroprozessor-CPU an das Zwischenraum-Mess-Subsystem und das Endgerät gesendet werden;
• 3) der Signalumwandlungsschaltkreis wandelt die Widerstandssignale des Verschiebungssensors in Spannungssignale um und führt unter der Steuerung der Mikroprozessor-CPU eine A/D-Umwandlung der Spannungssignale durch, wobei die CPU einen Änderungsbetrag des Zwischenraums berechnet und diesen über den Drahtloskommunikationsschaltkreis in Echtzeit an das Endgerät sendet;
• 4) das Endgerät nimmt die Dateninformation des Zwischenraum-Mess-Subsystems und des Abstandsmess-Subsystems in Echtzeit auf, addiert den Zwischenraum-Änderungsbetrag zu einem Anfangswert des Zwischenraums, um so einen Zwischenraumwert einer Echtzeit-Position zu erhalten, wobei das Endgerät dann den Zwischenraumwert und den in Schritt 2) entsprechend dem Zwischenraumwert hergeleiteten Echtzeit-Abstand bearbeitet, anzeigt und abspeichert; und
• 5) wenn das Zwischenraum-Mess-Subsystem einen Ausgang (d. h. Rolltreppenende) erreicht, dann stoppt die Rolltreppe und der Test endet.

An operating method for measuring a safety distance between steps and edge ledges of an escalator and for locating hidden hazards uses the system according to the present utility model, the method comprising the following steps:

• 1) preparation of a measurement;
• a) marking an initial position: a marking is made with a marking pin at positions that are symmetrical left and right on the sidebars, respectively at the beginning of the escalator, that is, at a zero-movement position of the sensor, where the space value between the steps and the edge ledges of the escalator at the two marked positions are measured using a straight line ruler or a distance gauge as the initial values of the gap;
• b) Installation of the Gap Measuring Subsystem: The displacement sensor is mounted and fixed on the sensor mounting base with the clamping base and clamping plate of the sensor mounting base adjusted to ensure that the displacement sensors on both sides match the two markings made in step a) coincide, wherein the fastener is rotated to attach and fix the displacement sensor on the escalator foot plate of the escalator;
• c) Installation of the distance measuring subsystem: the distance measuring device is fixed on the escalator through the suction disc of the scaffold, with the swivel arm of the scaffold being adjusted so as to allow the rubber wheel to press firmly on the horizontal segment of the escalator steps;
• d) System Startup: The power switches on the terminal, the interleaved gap computer processing module, and the embedded interworking computer processing module are turned on, and a terminal test software is started to perform a communication detection; and if the communication is good, the process proceeds to the next step;
• e) Setting basic information: The ID number of the escalator to be detected and corresponding data information to be acquired are input under a parameter setting option; and
• f) Setting Initial Values: The initial gap values measured in step a) are input to the system.
• 2) The escalator is driven at a maintenance speed with the rubber wheel of the distance measuring subsystem moving along the steps, the rotary encoder generating pulse signals, the pulse shaping circuit performing shaping and filtering on the pulse signals transmitted from the rotary encoder, and then the pulse signals for calculation, sends to the step run distance measuring circuit so as to derive the step running speed and the distance sent via the wireless communication circuit in real time under the control of the microprocessor CPU to the gap measuring subsystem and the terminal;
• 3) the signal conversion circuit converts the resistance signals of the displacement sensor into voltage signals and performs A / D conversion of the voltage signals under the control of the microprocessor CPU, the CPU calculating an amount of change of the gap and sending it to the terminal via the wireless communication circuit in real time ;
• 4) the terminal receives the data information of the gap measuring subsystem and the distance measuring subsystem in real time, adds the gap changing amount to an initial value of the gap so as to obtain a gap value of a real time position, the terminal then sets the gap value and processes, displays and stores the real-time distance derived in step 2) according to the space value; and
• 5) when the gap measuring subsystem reaches an exit (ie escalator end), then the escalator stops and the test ends.

The above embodiments are merely the preferred embodiments of the present invention, and the present invention is not limited thereto, and all embodiments are intended to be within the scope of the present invention as long as they achieve the technical effects of the present invention by the same or similar means.

Claims (8)

A system for measuring a safety distance between steps and ledges of an escalator and for locating hidden hazards, the system comprising: a distance measuring subsystem communicating with a terminal, the distance measuring subsystem being used to measure a running distance of the stages in real time and to transmit the measured distance data information to the terminal for processing; a gap measuring subsystem, wherein the gap measuring subsystem is used to detect in real time the changes in the gap between the steps and sidebars and to transmit the gap data information to the terminal for processing; and a terminal, wherein the terminal is used for receiving the data information of the distance measuring subsystem and the gap measuring subsystem for processing and display. A system for measuring a safety distance between escalator steps and sidewalks and for locating hidden hazards according to claim 1, wherein the distance measuring subsystem comprises a distance measuring device and an integrated distance computer processing module. A system for measuring a safety distance between steps and ledges of an escalator and for locating hidden hazards according to claim 2, wherein the distance measuring means comprises: a rubber wheel, and a rotary encoder connected to the rubber wheel via a coupling, wherein the distance measuring device is mounted on a horizontal segment of the edge of the escalator via a scaffold with a suction disc. A system for measuring a safety distance between escalator steps and sidebars and for locating hidden hazards according to claim 2, wherein the included distance computer processing module comprises: a microprocessor CPU connected to a data memory and a wireless communication circuit, respectively, an input end of the microprocessor CPU connected to a step track distance measuring circuit and a charging and power supply circuit; a data store; a wireless communication circuit, wherein the integrated distance computer processing module communicates with the terminal via the wireless communication circuitry; a charging and power supply circuit connected to a rechargeable lithium battery; a step run distance measuring circuit, wherein an input end of the step run distance measuring circuit is connected to a pulse shaping circuit; a pulse shaping circuit. A system for measuring a safety distance between escalator steps and sidewalks and for locating hidden hazards according to claim 1, wherein the gap measuring subsystem comprises: a sensor base; a sensor mounted on the sensor base; and an integrated space computer editing module. A system for measuring a safety distance between escalator steps and ledges and for locating hidden hazards according to claim 5, wherein the sensor comprises a contact type displacement sensor. The system for measuring a safety distance between steps and ledges of an escalator and for locating hidden hazards according to claim 5, wherein the sensor base comprises: a clamp base, the clamp base being provided with a first through-hole; a clamping plate hooked to an upper end of the clamping base, the clamping plate having a second through hole at a Position corresponding to the first through hole in the clamp base, the lower ends of the clamp base and the clamp plate being inserted into tooth slots of an escalator foot plate at the same time; a fastener, wherein the clamp base is connected to the clamping plate by the fastener by the fastener passes through both the first through hole and the second through hole. The system for measuring a safety distance between escalator steps and sidewalks and for locating hidden hazards according to claim 5, wherein the included gap computer processing module comprises: a microprocessor CPU, each connected to a data memory and a wireless communication circuit, an input end of the microprocessor CPU connected to a charging and power supply circuit and an A / D converter; a data store; a signal conversion circuit; an A / D converter, wherein an input end of the A / D converter is connected to the signal conversion circuit; a charging and power supply circuit connected to a rechargeable lithium battery; and a wireless communication circuit, wherein the embedded gap computer processing module communicates with the terminal via the wireless communication circuitry.

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