CN215813798U - Enclose fender intelligent monitoring system - Google Patents

Abstract

The utility model discloses an intelligent enclosure monitoring system, which comprises: the sleeving switch comprises a metal spring piece and a metal piece, wherein the metal spring piece is arranged along the inner wall of the sleeve of the enclosure in a shrinking mode towards the center of the sleeve, and the metal piece is arranged on the outer side face of the hook of the enclosure; two ends of each enclosure unit are respectively provided with a sleeve joint switch; the digital label sensors are multiple, each digital label sensor corresponds to one enclosure unit, and each digital label sensor is connected with one of the metal spring pieces and the metal pieces of the two ends of the corresponding enclosure unit in a sleeved mode through a lead; the data acquisition and transmission device is connected to the other one of the metal spring piece and the metal piece of the switch sleeved at the two ends of each enclosure unit through a lead; and the server is in network connection with the data acquisition and transmission device and is used for monitoring the connection state of the enclosure. The utility model can monitor the connection state of the enclosure, and can monitor the specific position of the baffle plate to be removed and the removed number when the enclosure is monitored to be in the removed state.

Description

Enclose fender intelligent monitoring system

Technical Field

The utility model relates to the field of construction barriers, in particular to an intelligent monitoring system for a barrier.

Background

In the building construction process, high-altitude falling and falling objects are one of main reasons for safety accidents of building engineering, so that strict protection is required to be carried out on an adjacent opening in the building engineering. The fender is kept apart and is protected to the adoption usually at present job site, nevertheless encloses in the work progress and often influences the construction and is demolishd to keep off, and construction operation personnel do not in time resume after the construction completion and enclose when keeping off the installation, just have great potential safety hazard. The management of the current building site enclosure still depends on the traditional patrol of security personnel, and the construction team is reminded to recover in time when the enclosure is found to be missing. The method depends on manual inspection, and is influenced by multiple factors such as the configuration quantity of safety management personnel, management experience, management efficiency and the like, so that the defect of the enclosure cannot be timely found, and great potential safety hazards are brought. The safety barrier with the automatic alarm function has the advantages that whether the blocking piece of the barrier is detached or not can be judged, the specific position of the blocking piece cannot be judged, the detached number of the blocking pieces cannot be monitored, safety management personnel still need to patrol to find the missing blocking piece for recovery, and accordingly the defects that the barrier is fuzzy in monitoring and inaccurate are caused are overcome.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that an intelligent enclosure monitoring system is provided to solve the problem that the positions and the number of the removed enclosures cannot be accurately monitored.

In order to solve the technical problems, the technical scheme provided by the utility model is as follows: an enclosure intelligent monitoring system, comprising:

the sleeving switch comprises a metal spring piece and a metal piece, wherein the metal spring piece is of a split structure, the metal spring piece is arranged along the inner wall of the sleeve of the enclosure in a shrinkage mode towards the center of the sleeve, and the metal piece is arranged on the outer side face of the hook of the enclosure; the two ends of each enclosure unit of the enclosure are respectively provided with one sleeving switch;

the digital label sensors are provided with numbers, each digital label sensor corresponds to one enclosure unit, and each digital label sensor is connected with one circuit of the metal spring piece and the metal piece of the sleeve switch at the two ends of the corresponding enclosure unit through a conducting wire;

the data acquisition and transmission device is connected to the other one of the metal spring piece and the metal piece of the sleeve switch at the two ends of each enclosure unit through a lead;

and the server is in network connection with the data acquisition and transmission device and is used for monitoring the connection state of the enclosure.

Further, the intelligent enclosure monitoring system provided by the utility model further comprises:

the insulating board is arranged on the lower portion of each upright post of the enclosure, and the insulating board is provided with a buckle.

Further, the intelligent enclosure monitoring system provided by the utility model further comprises:

and the wire groove plate is arranged on the insulating plate between the two adjacent stand columns through the buckles.

Further, the intelligent enclosure monitoring system provided by the utility model further comprises:

and the binding post is arranged on the insulating plate and on the metal piece of the sleeve switch.

Further, according to the enclosure intelligent monitoring system provided by the utility model, an insulating part is arranged between the metal part and the hook.

Furthermore, the enclosure intelligent monitoring system provided by the utility model comprises a data acquisition and transmission device and a controller, wherein the data acquisition and transmission device is connected with the controller and is provided with an acquisition module, a transmission module and a power supply module.

Furthermore, according to the enclosure intelligent monitoring system provided by the utility model, the sleeve switch is arranged on the sleeve and the hook below each enclosure unit.

Furthermore, in the enclosure intelligent monitoring system provided by the utility model, each numbered digital label sensor is arranged on the baffle of the corresponding enclosure unit.

Further, according to the enclosure intelligent monitoring system provided by the utility model, the sleeves are arranged on two sides of the blocking piece of the enclosure, and the hooks are arranged on the stand columns of the enclosure.

Further, according to the enclosure intelligent monitoring system provided by the utility model, the hooks are arranged on two sides of the blocking piece of the enclosure, and the sleeve is arranged on the upright post of the enclosure.

Compared with the prior art, the utility model has the following beneficial effects:

when the sleeve and the hook at the two ends of a certain enclosure unit are in a connection state, each metal spring piece of the enclosure unit is in contact with the corresponding metal piece of the enclosure unit to enable the sleeve switch to be in a connection state, and the digital label sensor of the enclosure unit forms a conduction loop with the data acquisition and transmission device through the sleeve switch in the connection state; at the moment, the data acquisition and transmission device can acquire the electric signals of the digital label sensors with corresponding numbers, the data acquisition and transmission device transmits the electric signals of the digital label sensors to the server, and the server judges that the digital label sensors are in an online state; and judging that the connection state of the enclosure unit corresponding to the digital label sensor is the installation state. When all the sleeves and the hooks at the two ends of the enclosing and blocking unit of the enclosing and blocking are in a connection state, parallel loops are formed among the digital label sensors, so that the data acquisition and transmission device can acquire the state of each digital label sensor, and when all the digital label sensors are in an on-line state, the server judges that the enclosing and blocking unit is in an installation state.

When at least one of a sleeve and a hook at two ends of a certain enclosure unit is in a dismantling state, the metal spring piece at least one end of the enclosure unit is separated from the corresponding metal piece to enable the sleeve switch at least one end to be in a disconnection state, and the digital label sensor of the enclosure unit is disconnected with the data acquisition and transmission device through the sleeve switch in the disconnection state to form a conduction loop; at the moment, the data acquisition and transmission device cannot acquire the electric signals of the digital label sensor with the corresponding number, the server judges that the digital label sensor is in an off-line state, judges that the blocking piece of the enclosure unit corresponding to the digital label sensor is detached, and determines the detached position of the enclosure according to the corresponding relation between the digital label sensor and the number of the enclosure unit. And summing the removed blocking sheets to judge the removed number. And when one digital label sensor is in an off-line state, the server judges that the enclosure is in a dismantling state.

Drawings

FIG. 1 is a schematic structural view of the enclosure;

FIG. 2 is a schematic structural diagram of an intelligent enclosure system distributed on an enclosure;

FIG. 3 is a schematic view of the installation structure of the insulating plate, the slot plate, the binding post and the conducting wire;

FIG. 4 is a schematic cross-sectional view taken at A-A in FIG. 3;

FIG. 5 is a schematic view of a hook and metal member thereon;

FIG. 6 is an enlarged schematic view of the sleeve and the hook of the enclosure with the sleeve switch;

fig. 7 is a block schematic diagram of a data acquisition and transmission device.

Shown in the figure:

100. an intelligent enclosure system; 110. the system comprises a socket switch, 111, a metal piece, 112, a metal spring piece, a metal contact, 120, a digital label sensor, 130, a data acquisition and transmission device, 131, a controller, 132, an acquisition module, 133, a transmission module, 134, a power supply module, 140, a server, 150, a wire, 160, an insulating plate, 161, a buckle, 170, a trunking plate, 180 and a binding post;

200. the enclosure comprises an enclosure body 210, a stand column 211, a hook 220, a baffle plate 221 and a sleeve.

Detailed Description

The utility model is described in detail below with reference to the attached drawing figures:

referring to fig. 1 to fig. 7, an embodiment of the utility model provides an enclosure intelligent monitoring system 100, which may include:

the sleeve switch 110 comprises a metal spring sheet 112 and a metal piece 111 which are of a split structure, wherein the metal spring sheet 112 is arranged along the inner wall of a sleeve 221 of the enclosure 200 in a shrinking mode towards the center of the sleeve 221, and the metal piece 111 is arranged on the outer side face of a hook 211 of the enclosure 200; wherein, two ends of each enclosure unit of the enclosure 200 are provided with one said sleeve switch 110. That is, the sleeve switch 110 is not an integral structure, but a separate structure, and is turned on or off depending on whether the sleeve 211 and the hook 211 are sleeved or not. In order to improve the contact effect, the upper end of the metal spring plate 112 may be provided with a metal contact 113, and the metal contact 113 can maintain good electrical contact with the metal member 111.

The digital label sensors 120 are a plurality of numbered digital label sensors, each digital label sensor 120 corresponds to one enclosure unit, and each digital label sensor 120 is connected with one circuit of the metal spring piece 112 and the metal piece 111 of the sleeve switch 110 at two ends of the corresponding enclosure unit through a conducting wire 150. The digital label sensor 120 is a digital label using a known technology, for example, the digital label sensor 120 stores number information or coded information, where the number information may be a number, a letter, a symbol, or other identification.

And the data acquisition and transmission device 130 is connected to the other one of the metal spring piece 112 and the metal piece 111 of the sleeve switch 110 at two ends of each enclosure unit through a lead 150.

And the server 140 is in network connection with the data acquisition and transmission device 130 and is used for monitoring the connection state of the enclosure 200. Wherein the attached state of the enclosure 200 includes an installed state and a removed state. Wherein the server 140 may or may not be located at the site of the enclosure 200.

Referring to fig. 2 to fig. 4, in order to avoid exposing more wires 150, the enclosure intelligent monitoring system 100 according to the embodiment of the present invention may further include:

and an insulating plate 160 disposed at the lower part of each upright of the enclosure 200, wherein the insulating plate 160 is provided with a fastener 161. Wherein the insulating plate 160 is an insulator.

And the wire groove plate 170 is arranged on the insulating plate 160 between two adjacent upright columns 210 through the buckles 161. The lower wires 150 disposed between the posts 210 of the enclosure 200 are hidden by the arrangement of the slot plate 170, and are quickly disassembled and assembled with the slot plate 170 through the hooks 161 of the insulating plate 160.

Referring to fig. 2 to fig. 4, in order to facilitate wiring, the enclosure intelligent monitoring system 100 according to the embodiment of the present invention may further include:

the terminals 180 include the terminals 180 disposed on the insulating plate 160 and the terminals 180 disposed on the metal member 111 of the socket switch 110, so as to facilitate the switching between the plurality of wires 150.

In order to avoid electrification of the enclosure 200 and improve construction safety, an insulating member may be disposed between the metal member 111 and the hook 211 of the enclosure intelligent monitoring system 100 according to the embodiment of the present invention. An insulator may also be provided between the inner wall of the bushing 221 and the metal spring plate 112 of the sleeve switch 110. Wherein the insulating member may be a rubber pad or the like.

Referring to fig. 7, in the enclosure intelligent monitoring system 100 according to the embodiment of the present invention, the data acquisition and transmission device 130 includes a controller 131, and an acquisition module 132, a transmission module 133 and a power supply module 134 are connected to the controller 131. Wherein the power supply module 134 provides power supply for the digital acquisition and transmission device 130, the acquisition module 132 can be a narrowband internet of things module for acquiring whether the digital tag sensor has an electric signal, and the transmission module 133 can be a wireless transmission module 133 for transmitting the data of the acquisition module 132 to the server 140.

Referring to fig. 2, in the enclosure intelligent monitoring system 100 according to the embodiment of the present invention, the sleeve switch 110 is disposed on the sleeve 221 and the hook 211 below each enclosure unit. It can reduce the winding of wire 150 above fence 200, avoid breaking due to material or equipment contact during construction operation. In the enclosure intelligent monitoring system 100 provided by the embodiment of the present invention, four hooks 211 between two adjacent upright columns 210 of each enclosure unit and four corresponding sleeves 221 on the baffle 220 are taken as examples. Namely, the two sleeves 221 and the hook 211 below each enclosure unit are used for setting the sleeve switch 110, and of course, the sleeve switch 110 can be set by the sleeve 221 and the hook 211 above under certain conditions.

Referring to fig. 2, in the enclosure intelligent monitoring system 100 according to the embodiment of the present invention, the digital label sensor 120 with each number is disposed on the blocking sheet 220 of the corresponding enclosure unit. For example: the sequential signals of the baffle plates 220 of the enclosure from left to right are (i), (ii), etc., and the numbers of the digital label sensor 120 from left to right can be (1), (2), etc., correspondingly.

Referring to fig. 2, in the enclosure intelligent monitoring system 100 according to the embodiment of the present invention, the sleeves 221 may be disposed on two sides of the blocking piece of the enclosure 200, and the hooks 211 may be disposed on the upright posts 210 of the enclosure 200. Of course, as an alternative, the hooks 211 may be disposed on both sides of the blocking piece of the enclosure 200, and the sleeves 221 may be disposed on the pillars 210 of the enclosure 200.

In the enclosure intelligent monitoring system 100 provided in the embodiment of the present invention, when the sleeve 221 and the hook 211 at both ends of a certain enclosure unit are both in a connection state, each metal spring piece 112 of the enclosure unit contacts with the corresponding metal piece 111 thereof to make the socket switch 110 in a connection state, and the digital tag sensor 120 of the enclosure unit forms a conduction loop with the data acquisition and transmission device 130 through the socket switch 110 in the connection state; at this time, the data acquisition and transmission device 130 can acquire the electrical signals of the digital tag sensors 120 with corresponding numbers, the data acquisition and transmission device 130 transmits the electrical signals of the digital tag sensors 120 to the server 140, and the server 140 determines that the digital tag sensors 120 are in an online state; and determines that the connection state of the enclosure unit corresponding to the digital tag sensor 120 is the installation state. When the sleeves 221 and the hooks 211 at the two ends of all the enclosure units of the enclosure 200 are in a connection state, a parallel loop is formed between the digital tag sensors 120, so that the data acquisition and transmission device 130 can acquire the state of each digital tag sensor 120, and when all the digital tag sensors 120 are in an online state, the server 140 determines that the enclosure 200 is in an installation state.

In the enclosure intelligent monitoring system 100 provided in the embodiment of the present invention, when at least one of the sleeve 221 and the hook 211 at two ends of a certain enclosure unit is in a detached state, the metal spring piece 112 at least one end of the enclosure unit is separated from the corresponding metal piece 111, so that the socket switch 110 at least one end is in an off state, and the digital tag sensor 120 of the enclosure unit is disconnected from the data acquisition and transmission device 130 through the socket switch 110 in the off state to form a conducting loop; at this time, if the data acquisition and transmission device 130 cannot acquire the electrical signal of the digital tag sensor 120 with the corresponding number, the server 140 determines that the digital tag sensor 120 is in an off-line state, determines that the blocking piece of the enclosure unit corresponding to the digital tag sensor 120 is removed, and determines the removed position of the enclosure 200 according to the corresponding relationship between the digital tag sensor 120 and the enclosure unit number. And summing the removed blocking sheets to judge the removed number. When one of the digital label sensors 120 is in the offline state, the server 140 determines that the enclosure 200 is in the detached state.

When the enclosure 200 is monitored to be in the removal state, the enclosure intelligent monitoring system 100 provided by the embodiment of the utility model can monitor which specific blocking piece 220 is removed and the number of removed blocking pieces. Wherein the surround 200 is not limited to the specific structure and examples shown in the figures.

The present invention is not limited to the above-described specific embodiments, and it is apparent that the above-described embodiments are some, not all, of the embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the utility model, are within the scope of the utility model. Other levels of modification and variation of the present invention may be made by those skilled in the art. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims.

Claims (10)

1. The utility model provides an enclose fender intelligent monitoring system which characterized in that includes:

the sleeving switch comprises a metal spring piece and a metal piece, wherein the metal spring piece is of a split structure, the metal spring piece is arranged along the inner wall of the sleeve of the enclosure in a shrinkage mode towards the center of the sleeve, and the metal piece is arranged on the outer side face of the hook of the enclosure; the two ends of each enclosure unit of the enclosure are respectively provided with one sleeving switch;

the digital label sensors are provided with numbers, each digital label sensor corresponds to one enclosure unit, and each digital label sensor is connected with one circuit of the metal spring piece and the metal piece of the sleeve switch at the two ends of the corresponding enclosure unit through a conducting wire;

the data acquisition and transmission device is connected to the other one of the metal spring piece and the metal piece of the sleeve switch at the two ends of each enclosure unit through a lead;

and the server is in network connection with the data acquisition and transmission device and is used for monitoring the connection state of the enclosure.

2. The enclosure intelligent monitoring system of claim 1, further comprising:

the insulating board is arranged on the lower portion of each upright post of the enclosure, and the insulating board is provided with a buckle.

3. The enclosure intelligent monitoring system of claim 2, further comprising:

and the wire groove plate is arranged on the insulating plate between the two adjacent stand columns through the buckles.

4. The enclosure intelligent monitoring system of claim 3, further comprising:

and the binding post is arranged on the insulating plate and on the metal piece of the sleeve switch.

5. The enclosure intelligent monitoring system of claim 1, wherein an insulating member is disposed between the metal member and the hook.

6. The enclosure intelligent monitoring system of claim 1, wherein the data acquisition and transmission device comprises a controller, and an acquisition module, a transmission module and a power supply module are connected with the controller.

7. The enclosure intelligent monitoring system of claim 1, wherein the sleeve switch is disposed on the sleeve and the hook below each enclosure unit.

8. The enclosure intelligent monitoring system of claim 1, wherein each numbered digital label sensor is disposed on a flap of a respective enclosure unit.

9. The enclosure intelligent monitoring system of claim 1, wherein the sleeves are arranged on two sides of a barrier sheet of the enclosure, and the hooks are arranged on a stand column of the enclosure.

10. The enclosure intelligent monitoring system of claim 1, wherein the hooks are disposed on both sides of a barrier sheet of the enclosure, and the sleeves are disposed on a stand column of the enclosure.

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