CN216892127U - Swing gate passing detection device and passing swing gate - Google Patents

Abstract

The swing gate passing detection device comprises a device body, the device body comprises a tray and an induction panel arranged on the upper side of the tray, the periphery of the tray is provided with a side edge, the side edge and the tray are enclosed to form a groove body, the induction panel is movably arranged in the groove body, and the induction panel is matched with the specification of the groove body; be provided with induction element between induction panel and the tray, induction element's both ends offset with induction panel and tray respectively, and the power that induction panel received transmits to induction element. The application provides a current detection device of pendulum floodgate, through setting up response panel and tray, and be provided with the induction element between response panel and tray, the induction element is used for detecting the pressure that the response panel received, can control the pendulum floodgate to open when detecting pressure and being greater than the setting value to control the pendulum floodgate and close after pressure reduces, can guarantee that the pedestrian controls the pendulum floodgate promptly and opens before getting into the floodgate, and the conduction is more timely.

Description

Swing gate passing detection device and passing swing gate

Technical Field

The application belongs to the technical field of the current design of swing gate, and more specifically relates to a current detection device of swing gate and current swing gate.

Background

The swing gate machine is a control device of a pedestrian flow channel. The gate machine is used for places where people need to control the entrance and exit, such as dining halls, hotels, museums, gymnasiums, clubs, subways, stations, wharfs and the like, and people can pass through the channel orderly by using the gate machine. The intelligent swing gate machine is combined with devices of biological identification technology (such as human face identification, fingerprint identification and the like), two-dimensional code identification, IC card reading and writing and the like to form an intelligent swing gate machine, and the intelligent swing gate machine is combined with a computer and entrance guard attendance and charging management software to form an intelligent swing gate machine comprehensive management system, so that the functions of entrance guard, attendance, current limiting and the like can be realized, and the charging function is also realized.

The existing swing gate machine generally comprises a control system, a power supply and the like, a lengthened swing arm (the swing arm exceeds the infrared region of the gate machine) is used, delay detection is carried out by adopting a radar and a reflection tube or a program (the condition that pedestrians pass through the gate machine is ensured for a long time every time the gate is opened), and the safe passing of the swing gate is realized by the method.

However, the conventional swing gate machine has a limit in detection distance and a short transit time.

Disclosure of Invention

An object of the embodiment of the application is to provide a current detection device of pendulum floodgate and current pendulum floodgate to there is the restriction in the pendulum floodgate machine detection distance that solves existence among the prior art, and the short problem of transit time.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: provided is a swing gate passage detection device, including:

the device body comprises a tray and an induction panel arranged on the upper side of the tray, wherein side edges are arranged on the periphery of the tray, the side edges and the tray are enclosed to form a groove body, the induction panel is movably arranged in the groove body, and the induction panel is matched with the groove body in specification;

an induction unit is arranged between the induction panel and the tray, two ends of the induction unit are respectively abutted against the induction panel and the tray, and force applied to the induction panel is transmitted to the induction unit.

Optionally, the sensing unit includes a first control processing unit and a gravity sensor, the first control processing unit is electrically connected to the gravity sensor, and the first control processing unit processes and transmits a stress signal of the gravity sensor.

Optionally, the first control processing unit has a preset value, and when the force-receiving signal is greater than or equal to the preset value, the first control processing unit sends a first control signal;

when the stress signal is smaller than a preset value, the first control processing unit sends out a second control signal; or the first control processing unit does not send out signals.

Optionally, the gravity sensor is provided with a plurality of gravity sensors, the plurality of gravity sensors are uniformly arranged between the sensing panel and the tray at intervals, and the plurality of gravity sensors are respectively electrically connected with the first control processing unit.

The application also provides a passing swing gate, which comprises a gate body and the swing gate passing detection device;

the gate machine body is provided with a passing channel, the passing channel is provided with a first opening and a second opening, and the swing gate passing detection device is arranged at the first opening and/or the second opening.

Optionally, the gate body includes two chassis arranged oppositely and in parallel, and the first opening and the second opening are respectively formed in two directions between the two chassis;

a pendulum gate is disposed between the first opening and the second opening.

Alternatively, the swing gate may be moved toward the first opening or the second opening at the same time.

Optionally, the two swing gate passing detection devices are arranged at the first opening and the second opening respectively.

Optionally, the gate body further includes a second control processing unit and an infrared assembly, the infrared assembly is disposed between the two cases, the second control processing unit is disposed in the case, and the second control processing unit is electrically connected to the swing gate passage detection device, the infrared assembly and the swing gate respectively.

Optionally, the infrared assembly includes multiple sets of infrared sensors, the multiple sets of infrared sensors are respectively disposed at upper and lower positions of the two cases, and a transmitting direction of the infrared sensor is toward another case.

The application provides a current detection device of pendulum floodgate's beneficial effect lies in: compared with the prior art, the current detection device of swing gate of this application is through setting up response panel and tray, and is provided with induction element between response panel and tray, and induction element is used for detecting the pressure that the response panel received, can control the swing gate to open when detecting pressure and being greater than the setting value to control the swing gate and close after pressure reduces, can guarantee that the pedestrian controls the swing gate promptly and opens before getting into the floodgate machine, and the conduction is more timely.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the embodiments or the prior art description will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings may be obtained according to these drawings without inventive labor.

Fig. 1 is a schematic structural diagram of a swing gate passage detection device provided in an embodiment of the present application;

fig. 2 is a first schematic view of a matching structure of the swing gate passage detection device and the passage swing gate provided in the embodiment of the present application;

fig. 3 is a schematic view of a matching structure of the swing gate passage detection device and the passage swing gate according to the embodiment of the present application;

fig. 4 is a schematic circuit structure diagram of a pass swing gate according to an embodiment of the present disclosure.

Wherein, in the figures, the respective reference numerals:

1-swing gate passing detection device; 2-a gate body; 10-the device body; 11-a tray; 12-a sensing panel; 13-lateral; 14-a trough body; 20-a sensing unit; 21-a first control processing unit; 22-a gravity sensor; 30-a case; 40-swing gate; 50-an infrared sensor; 201-a second control processing unit.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings that is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to fig. 4, a swing gate passage detection device according to an embodiment of the present application will be described. The embodiment of the application provides a current detection device 1 of pendulum floodgate, and in this embodiment, current detection device 1 of pendulum floodgate includes device body 10, and device body 10 includes tray 11 and sets up the response panel 12 at tray 11 upside, and 11 week sides of tray enclose and are equipped with side 13, and side 13 and tray 11 enclose to close and form cell body 14, and response panel 12 movable mounting is in cell body 14, and the specification phase-match of response panel 12 and cell body 14.

Wherein, tray 11 is as a plane part, and the side of the week side of tray 11 encloses and is equipped with round side 13, and the relative height of side 13 is higher than tray 11 is whole, and side 13 encloses and closes and set up on the side of tray 11. It can be understood that a slot 14 with an opening is formed between the side 13 enclosing the periphery of the tray 11 and the tray 11, the opening faces away from the tray 11, and the induction panel 12 is installed into the slot 14 through the opening.

It should be noted that the sensing panel 12 is usually configured to match the slot 14, that is, the sensing panel 12 can move up and down in the slot 14, so as to sense gravity. For example, when the sensing panel 12 is installed in the slot 14, a certain gap is formed between the peripheral side of the sensing panel 12 and the side 13 of the slot 14, so that the sensing panel 12 can be ensured to move in the slot 14 close to or away from the slot bottom of the slot 14, which is not limited in this embodiment.

In addition, in order to ensure the detection effect of the swing gate passage detection device, the swing gate passage detection device needs to detect the passing state of a passing person, so that the control of the opening and closing of the gate is ensured. For this reason, in the present embodiment, the sensing unit 20 is disposed between the sensing panel 12 and the tray 11, both ends of the sensing unit 20 respectively abut against the sensing panel 12 and the tray 11, and the force received by the sensing panel 12 is transmitted to the sensing unit 20. When the swing gate passage detection device 1 is installed, the device body 10 is generally placed on a plane, and the sensing unit 20 senses that a passing person passes through the device body 10. For this purpose, the device body 10 is fixed on a plane, i.e. the bottom of the tray 11 is against the ground plane, and when a pedestrian steps on the sensing panel 12, the sensing panel 12 is forced to move towards the tray 11. In this process, during the process that the sensing panel 12 moves toward the tray 11, the sensing unit 20 located between the sensing panel 12 and the tray 11 detects the force applied by the sensing panel 12 toward the tray 11.

For example, the sensing unit 20 is typically configured with a pressure threshold to determine the pressure transmitted by the sensing panel 12. The pressure threshold is usually set to be smaller than the pressure applied by a single step when a person walks, when no person passes through the pressure threshold, only the sensing panel 12 applies the gravity of the sensing panel 12 towards the direction of the tray 11, and at this time, the sensing unit 20 determines that the stress condition is smaller than the pressure threshold, and the passing swing gate is in a standby state; when a pedestrian passes by and steps on the induction panel 12, the induction panel 12 is stressed to move towards the direction of the tray 11 and transmits pressure to the induction unit 20, and when the induction unit 20 detects that the pressure is greater than or equal to a pressure threshold value, the induction unit 20 sends out a control signal and controls the passing swing gate to work and open; when the pedestrian passes, the sensing unit 20 detects that the pressure of the sensing panel 12 is recovered below the pressure threshold, and the sensing unit 20 controls the passing swing gate to be closed, so as to complete the control of opening and closing the passing swing gate.

For example, in the present embodiment, in order to ensure the sensing and controlling effects of the sensing unit 20, optionally, the sensing unit 20 includes a first control processing unit 21 and a gravity sensor 22, the first control processing unit 21 is electrically connected to the gravity sensor 22, and the first control processing unit 21 converts a stress signal of the gravity sensor 22 into an electrical signal and transmits the electrical signal to the passing swing gate, so as to complete the controlling effect on the passing swing gate. In this embodiment, optionally, the first control processing unit 21 has a preset value, and when the force-receiving signal is greater than or equal to the preset value, the first control processing unit 21 sends out a first control signal; when the stress signal is smaller than the preset value, the first control processing unit 21 sends out a second control signal; alternatively, the first control processing unit 21 does not issue a signal. For example, when the stress signal is greater than or equal to the preset value, the first control processing unit 21 determines that the pedestrian passes through, and at this time, the first control processing unit 21 sends a signal to control the passing swing gate to be opened, and at this time, the signal is a first control signal; when the stress signal is smaller than the preset value, two conditions exist at the moment, when no pedestrian passes through, the passing swing gate is always in a standby state, and the first control processing unit 21 does not send a signal at the moment; when the pedestrian leaves the sensing panel 12 after passing, the sensing panel 12 loses the treading pressure, and the first control processing unit 21 sends out a second control signal and controls the passing swing gate to be closed.

It should be noted that, in the present embodiment, in order to ensure uniformity and stability of supporting and sensing the sensing panel 12, optionally, a plurality of gravity sensors 22 are provided, a plurality of gravity sensors 22 are uniformly and intermittently disposed between the sensing panel 12 and the tray 11, and the plurality of gravity sensors 22 are respectively electrically connected to the first control processing unit 21. The uniformly arranged gravity sensors 22 sense the stress conditions of all the parts of the sensing panel 12, and the stress conditions are collectively conveyed to the first control processing unit 21 for judgment, so that the passing state of the pedestrian is judged, and the control of the passing swing gate is completed.

On the basis of the above embodiment, this application still provides a current pendulum floodgate, including floodgate machine body 2 and the current detection device 1 of foretell pendulum floodgate, floodgate machine body 2 is formed with current passageway, and current passageway both ends are provided with first opening and second opening, and the current detection device 1 setting of pendulum floodgate is at first opening and/or second opening part. That is, the swing gate passing detection device 1 may be disposed at the first opening, the swing gate passing detection device 1 may also be disposed at the second opening, and meanwhile, the swing gate passing detection device 1 may be disposed at both the first opening and the second opening, so as to complete the bidirectional detection.

The swing gate passage detection device provided in this embodiment is the same as the swing gate passage detection device in the above embodiments, and the technical effects achieved by the swing gate passage detection device are also the same, which is not described in detail in this embodiment.

The gate body 2 comprises two opposite and parallel chassis 30, and a first opening and a second opening are respectively formed between the two chassis 30 in two facing directions; a swing gate 40 is provided between the first opening and the second opening, and the moving direction of the swing gate 40 can be moved toward the first opening or toward the second opening at the same time.

Wherein, a passage is formed between the two machine boxes 30, and the swing gate 40 is arranged between the two machine boxes 30 to block the passage. After the control signal sent by the first control processing unit 21 in the swing gate passage detection device 1 is transmitted to the gate body 2, the effect of blocking and releasing pedestrians can be achieved by controlling the opening and closing of the swing gate 40.

In the present embodiment, the moving direction of the swing gate 40 is set to be capable of moving in two directions, that is, when a pedestrian enters from the first opening, the swing gate 40 is opened towards the side (i.e. the second opening direction) away from the pedestrian, so that the pedestrian can pass through smoothly, and the swing gate 40 does not block the pedestrian; or, when a pedestrian enters from the second opening, the swing gate 40 is opened toward the side away from the pedestrian (i.e., the first opening direction), so that the pedestrian can pass through smoothly, and the swing gate 40 does not block the pedestrian. The moving direction of the swing gate 40 is set to be bidirectional, so that both sides of the passing swing gate can be ensured to pass smoothly.

It should be noted that, in order to ensure the timeliness of detection when a pedestrian passes through, optionally, two swing gate passing detection devices 1 are provided, and the two swing gate passing detection devices 1 are respectively provided at the first opening and the second opening. When a pedestrian enters from the first opening and passes through the first opening after authorization, the swing gate passing detection device 1 positioned at the first opening detects a treading signal of the pedestrian, and at the moment, the gate body 2 is in an open state, so that the pedestrian can pass through the gate body conveniently; when the pedestrian passes through the swing gate passing detection device 1 at the second opening, the swing gate passing detection device 1 at the second opening receives the pressure signal, the swing gate passing detection device 1 at the second opening detects a pressure loss signal after the pedestrian leaves, and the gate body 2 is controlled to be closed at the moment; correspondingly, when a pedestrian enters from the second opening and passes through the authorization, the swing gate passing detection device 1 positioned at the second opening detects a treading signal of the pedestrian, and at the moment, the gate body 2 is in an open state, so that the pedestrian can pass through the gate; when the pedestrian passes through the swing gate passing detection device 1 at the first opening, the swing gate passing detection device 1 at the first opening receives the pressure signal, the swing gate passing detection device 1 at the first opening detects the pressure signal loss after the pedestrian leaves, and the gate body 2 is controlled to be closed at the moment.

For this purpose, optionally, the gate body 2 further includes a second control processing unit 201 and an infrared component, the infrared component is disposed between the two chassis 30, the second control processing unit 201 is disposed in the chassis 30, and the second control processing unit 201 is electrically connected to the swing gate passage detecting device 1, the infrared component and the swing gate 40, respectively. The gravity determination signal from the swing gate passage detection device 1 is transmitted to the second control processing unit 201, and the second control processing unit 201 controls the opening and closing of the swing gate 40. In order to ensure that the pedestrian is not stepping on the two swing gate passage detection devices when the pedestrian is located between the two swing gate passage detection devices 1, in order to avoid the second control processing unit 201 not receiving the signal to close the swing gate 40, an infrared component may be disposed between the two housings 30.

Wherein, infrared subassembly includes multiunit infrared sensor 50, and multiunit infrared sensor 50 sets up respectively in the upper and lower side position of two quick-witted casees 30, and infrared sensor 50's emission direction sets up towards another quick-witted case 30. It is understood that the chassis includes a chassis 30a and a chassis 30b, the emission direction of the infrared sensor 50 located on the chassis 30a is toward the chassis 30b, and the emission direction of the infrared sensor 50 located on the chassis 30b is toward the chassis 30 a. In the following, the pedestrian enters from the first opening and leaves from the second opening as an example, and the specific working process is based on the actual use condition, which is not limited in this embodiment.

Illustratively, when a pedestrian passes through the swing gate passage detection device 1 with the first opening, the pedestrian is located in the passage between the two chassis 30, and the infrared sensor 50 detects that the pedestrian passes through the passage and transmits a signal to the second control processing unit 201, and the second control processing unit 201 controls the swing gate 40 to keep the open state; when the swing gate passing detection device 1 located at the second opening detects that a pedestrian passes through and the infrared sensor 50 does not receive a blocking signal, it is determined that the pedestrian passes through the whole passing swing gate, and detection and control of the passing state of the pedestrian are completed.

In addition, in order to ensure that the passerby passes through the authorization and play a certain role in blocking, an authorization detection component can be arranged on the case 30, and whether the passerby has the right of passage or not can be determined by the additionally arranged authorization detection component; when the pedestrian does not have the right of passage, even if the swing gate passage detection device 1 located in the first opening detects the treading signal, the swing gate 40 is not controlled to be opened, only the pedestrian has the right of passage, and when the swing gate passage detection device 1 located in the first opening detects the treading signal, the swing gate 40 is opened, so that the user can pass through the swing gate, and the embodiment does not limit the opening.

The present invention is not intended to be limited to the particular embodiments shown and described, but is to be accorded the widest scope consistent with the principles and novel features herein disclosed.

Claims (10)

1. The utility model provides a current detection device of pendulum floodgate which characterized in that includes:

the device body comprises a tray and an induction panel arranged on the upper side of the tray, wherein side edges are arranged on the periphery of the tray, the side edges and the tray are enclosed to form a groove body, the induction panel is movably arranged in the groove body, and the induction panel is matched with the groove body in specification;

an induction unit is arranged between the induction panel and the tray, two ends of the induction unit are respectively abutted against the induction panel and the tray, and force applied to the induction panel is transmitted to the induction unit.

2. The swing gate passage detection device according to claim 1, wherein the sensing unit comprises a first control processing unit and a gravity sensor, the first control processing unit is electrically connected with the gravity sensor, and the first control processing unit processes and transmits a force signal of the gravity sensor.

3. The swing gate passage detection device according to claim 2, wherein the first control processing unit has a preset value, and when the force signal is greater than or equal to the preset value, the first control processing unit sends out a first control signal;

when the stress signal is smaller than a preset value, the first control processing unit sends out a second control signal; or the first control processing unit does not send out signals.

4. The swing gate passage detection device according to claim 2, wherein the gravity sensor is provided in plurality, the gravity sensors are uniformly and alternately arranged between the sensing panel and the tray, and the gravity sensors are electrically connected to the first control processing unit, respectively.

5. A passing swing gate, which is characterized by comprising a gate body and a swing gate passing detection device of any one of claims 1 to 4;

the gate body is provided with a passing channel, the passing channel is provided with a first opening and a second opening, and the swing gate passing detection device is arranged at the first opening and/or the second opening.

6. The transit swing gate of claim 5, wherein the gate body comprises two opposite and parallel cases, the first opening and the second opening being formed between the two cases in two facing directions, respectively;

a pendulum gate is disposed between the first opening and the second opening.

7. The transit swing gate of claim 6, wherein the swing gate is simultaneously movable toward the first opening or the second opening.

8. The passing swing gate of claim 5, wherein there are two of the swing gate passing detection devices, and the two swing gate passing detection devices are respectively disposed at the first opening and the second opening.

9. The passing swing gate of claim 6, wherein the gate body further comprises a second control processing unit and an infrared component, the infrared component is disposed between the two cases, the second control processing unit is disposed in the cases, and the second control processing unit is electrically connected with the swing gate passing detection device, the infrared component and the swing gate respectively.

10. The transit swing gate of claim 9, wherein the infrared assembly comprises a plurality of sets of infrared sensors, the infrared sensors are respectively disposed at upper and lower positions of the two housings, and the emission directions of the infrared sensors are disposed toward the other housing.

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