KR101409829B1 - Load sensing apparatus - Google Patents

Abstract

The present invention relates to a scaffold load sensing apparatus, and more specifically, to a scaffold load sensing apparatus which ensures stability of the scaffold installed for construction or maintenance of large-scale facilities such as a boiler installed in a thermal power plant by comprising a data collection unit separately installed at lower parts of vertical frames of a scaffold for sensing the load; a central processing unit collecting and processing the load data collected from the data transfer part in real-time; and a warning-issuing unit driven by communicating with the data collection unit, the central processing unit, or both. Hence, loads of the entire scaffold and loads for each of the vertical frames of the scaffold can be managed.

Description

[0001] LOAD SENSING APPARATUS [0002]

The present invention relates to a scaffold load sensing system,

More particularly, the present invention relates to a data collecting unit installed at a lower portion of each vertical frame of a scaffold for sensing a load for securing a scaffold installed for installation or maintenance of a large facility such as a boiler installed in a thermal power plant, A central processing unit for collecting and processing the load data collected in real time, and an alarm issuing unit for operating in conjunction with the data collecting unit or the central processing unit or both of them, And to a scaffold load sensing system capable of managing each load.

It is a temporary installation installed for the construction or maintenance of a large facility such as a large boiler installed in a thermal power plant, or for the construction or maintenance of a large building. It is used as a scaffold for material transportation, worker's passage and work.

Since scaffolds are large-sized facilities, the scaffold itself has a very large load, and the materials used for the construction or maintenance of the equipment are also very large in load, so there is a great risk of collapse due to an increase in load during operation.

Therefore, a worker working in a scaffold performs work at a very high altitude, so that if the scaffolding is not secured, the psychological stability may be lowered, leading to safety accidents. In particular, In case of carrying, the load transferred to each frame of the large scale scaffold is very large, so that collapse caused by this scaffold can lead to death of the operator.

In order to solve the above problems, Korean Patent No. 10-0714730 (Apr. 27, 2007) entitled " Multiple Safety Control System of High-Performance Work Vehicle "

[0003] In the conventional art, there is a problem that an abnormality occurs in a moment restricting device for restricting expansion and contraction of a boom of a high-altitude operation car when an operator is aboard a work platform of a high altitude operation car, The boom is excessively drawn out of the working range when causing contamination and malfunction, or the boom is damaged due to overloading due to overloading on the workbench and equipment overturn occurs. In this case, the maximum working range of the elevator car is limited to multiple And multi-safety control of a high-altitude work vehicle with the function of automatically limiting the maximum working range so that a safety accident of a small person due to overturning of the equipment is detected by sensing the overload, vibration, ≪ / RTI >

However, the above-mentioned prior art is a technology limited to a high-altitude work vehicle. In general, the conventional technique is applied to a scaffold installed in a large facility to prevent a safety accident and to protect a worker. There is a problem in that the weight management of the equipment can not be performed immediately on the spot based on the data processed by the data processing by collecting and processing the load burden individually in real time.

In addition, the above-mentioned prior art directly controls the work range of the workbench due to the load change and the like, and even if it is applied to a large facility such as a scaffold, the construction cost is increased and the cost efficiency is inferior. So that the versatility is very low.

Accordingly, the present invention has been made to solve the above-mentioned problems,

It is possible to detect a load burden of each vertical frame installed in a facility such as a scaffold in real time and to provide an operator with a risk of collapse according to a load change in real time to prevent a safety accident, A data collecting unit installed at a lower portion of a vertical frame to systematically perform safe load management of the facility, and a central processing unit for collecting and processing load data collected in the data collecting unit in real time, And to provide a load sensing system.

Further, the present invention includes an alarm issuing unit interlocked with the data collecting unit, the central processing unit, or all of them, so that the risk of collapse according to a load change is easily evacuated by the operator, and the follow- And to provide a scaffold load sensing system.

The present invention relates to a method for detecting a load on a scaffold with a data collector including a load cell including a load cell including a sensor built in a notch portion and a lower end portion of a vertical frame positioned so as to accurately and stably detect a load change of each vertical frame, System.

The present invention includes a first housing having a first accommodating portion for storing a load cell so as to facilitate storage and transportation of the scaffold load sensing system and having a control module connected to the load cell for processing and transmitting measured load data , And the first enclosure itself is constituted by a data relay unit of a data collecting unit.

Further, according to the present invention, there is provided a scaffold load detection system comprising a central processing unit, which is configured as a portable information processing terminal, for easy storage and transportation of a scaffold load sensing system, and a second enclosure having a second accommodating portion The purpose is to provide.

In order to achieve the above object, a scaffold load sensing system according to the present invention comprises:

A plurality of data collecting units installed in a lower portion of the vertical frame and including a load cell for sensing a load in real time;

A central processing unit for receiving and collecting the load data collected by the data collecting unit; And

And an alarm issuing unit operating in conjunction with the data collecting unit or the central processing unit or both of them,

If the load data measured in each load cell deviates from the load limit value of the previously stored individual vertical frame or the load data collected by the central processing unit exceeds the load limit of the entire pre-stored facility, the alarm issuing unit operates and issues a danger warning As shown in FIG.

Further, in the scaffold load sensing system according to the present invention, the load cell includes a notch portion on which a lower end of the vertical frame is placed, and a sensor built in a lower portion of the notch portion to sense a load.

In the scaffold load sensing system according to the present invention, the data collector may include a first housing having a first accommodating portion for accommodating the load cell, and a control module connected to the load cell to process and transmit the measured load data, .

In the scaffold load sensing system according to the present invention, the central processing unit may include a second housing including a portable information processing terminal, a second accommodation unit for storing the terminal, and a power supply unit for supplying power to the terminal .

The system for detecting gravity load according to the present invention includes a plurality of data collecting units including load cells installed under each of the vertical frames and a central processing unit for processing the collected load data in real time in connection with the data collecting unit , It is possible to detect the collapse risk more quickly and accurately by sensing the load load of individual vertical frames constituting a large facility such as a scaffold, and it provides a danger warning to the operator in real time, thereby evacuating the operator And subsequent measures for preventing collapse can be performed very quickly.

Further, since the gravity load sensing system according to the present invention collects and processes the load changes transmitted to the respective vertical frames, the weight management of the cargo loaded in the on-site facility and the load management of the facility itself are corrected in the field based on accurate load data It is easy to predict and prevent safety accidents such as collapse.

In addition, the scaffold load sensing system according to the present invention introduces an alarm issuing unit interlocked with the data collecting unit and the central processing unit, so that all workers can quickly and easily recognize danger alarms even in a high noise environment.

Further, the system for detecting a scaffold load according to the present invention can continuously reuse the load sensing system used after demolishing a facility to other facilities, so that the system is excellent in versatility and utility due to low cost.

In the scaffold load sensing system according to the present invention, the load can be accurately collected and utilized because the load can be managed independently of the vertical frame through the sensor unit having the lower end of the vertical frame and the sensor built in the sensor unit.

Further, the scaffold load sensing system according to the present invention can easily and quickly install the scaffold load sensing system at the time of installation of the facility, and can perform efficient work and convenient installation since efficient load management using wired and wireless is performed.

The scaffold load sensing system according to the present invention uses a first enclosure having a control module that is connected to a load cell and processes the measured load data as a data relay, so that it is convenient to store and transport the scaffold load sensing system, The load sensing system can be installed easily and quickly.

1 is a perspective view schematically showing an installation example of a scaffold load sensing system according to the present invention.
BACKGROUND OF THE INVENTION Field of the Invention [0001]
3 is a view for explaining a central processing unit of the scaffold load sensing system according to the present invention.
4 is a view for explaining an alarm issuing unit of the scaffold load sensing system according to the present invention.
5 to 8 are sample photographs of a scaffold load sensing system according to the present invention.
9 is a view for explaining waterproof means provided in a housing of a scaffold load sensing system according to the present invention.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

 In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

It is to be understood that the first to second aspects described in the present specification are merely referred to in order to distinguish between different components and are not limited to the order in which they are manufactured, It may not match.

In describing the scaffold load sensing system according to the present invention, when an unambiguous approximate direction reference is specified for convenience, referring to FIG. 1, the gravity acting direction is set to be downward, Unless otherwise specified in the description and the claims of the invention relating to the drawings, directions are specified in accordance with this standard.

Typically, the scaffold is supported by a plurality of vertical frames on the outside of the large facility, and is composed of multi-layer scaffolds connected horizontally to the vertical frames, and furthermore, a step or a simple elevator is provided for each worker.

The footrest is used not only as a footing for worker's passage and work, but also for carrying materials, stacking materials, and the like.

In this specification, a scaffold installed for maintenance or the like is described in a furnace K of a boiler installed in a thermal power plant or the like among facilities where scaffolds are used, and the structure of the scaffold installed is divided into four vertical frames S1 and S2 (S2). However, it is for convenience of explanation that the scaffold configuration differs according to the size of the facility, and accordingly, the number of configurations of the present invention is varied It is obvious that the invention can be applied.

Since the scaffold is installed for the maintenance or repair of a large facility, the load of the scaffold itself is large, and the load or the storage of a material having a large load is carried out on the scaffold of the scaffold. There is a large risk of collapse if an overload is transmitted to the scaffold or an excessive load is transferred to any one vertical frame of the scaffold. This collapse is caused by the operator's death In the field where large scaffolding is installed, it is important to manage the scaffold load.

Accordingly, the present invention proposes a scaffold load management apparatus for managing the load of a scaffold.

Hereinafter, a scaffold load sensing system according to the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 to 4, a scaffold load sensing system according to the present invention includes a data collecting unit 10 including a load cell 11 for sensing a load, A central processing unit 20 for providing load data to the user, and an alarm issuing unit 30 for issuing a danger warning.

The present invention is characterized in that the data collecting unit 10 is installed in all of the plurality of vertical frames S1 provided in the scaffold S to sense and measure the load transmitted to each vertical frame S1 in real time, The load data is transmitted to the central processing unit 20 and then collected and processed so that the load burden on each individual vertical frame S1 and the entire scaffold is given to the user so that the load management on the field can be performed in real time do.

The load cell 11 of the data collecting unit 10 is installed at the lower end of the vertical frame S1 when the scaffold is installed and then installed by installing a scaffold or by using a crane or the like, A method in which the load cell 11 is installed at the support position of the vertical frame S1 and then the scaffold is lowered can be considered.

The present invention enables transmission and reception of load data by connecting a plurality of data collecting units 10 and one central processing unit 20 to a long distance wireless communication network in the ISM band.

In addition, the data collecting unit 10 or the central processing unit 20 or all of them and the alarm issuing unit 30 are configured to operate in cooperation with each other through the wireless communication network.

2, the data collecting unit 10 includes a load cell 11 installed below the vertical frame S1 for directly sensing a load, load data measured in connection with the load cell 11, And a data relaying unit 13 for comparing and analyzing the accumulated load data with the pre-stored load limit value, and for transmitting the collected load data to the central processing unit 20.

The present invention is characterized in that a data collecting unit 10 composed of one data repeater 13 connected to each load cell 11 by wire or wireless is installed individually in a plurality of vertical frames S1, And the data relay device 13 compares, analyzes and processes the change of the measured load data individually.

The data repeater 13 of each data collecting unit 10 installed in the plurality of vertical frames S1 processes the load data measured by the load cell 11 and then stores the load data measured by the central processing unit 20 in real time And the central processing unit 20 receiving the load data of the individual vertical frames S1 collects all the load data and comprehensively analyzes the overall load burden transmitted to the scaffold S and provides it to the user, The load burden transmitted for each vertical frame S1 is individually analyzed and provided to the user.

Therefore, the present invention can prevent the load data measured in each load cell 11 from exceeding the load limit value of the previously stored individual vertical frame S1 or the load data collected from the central processing unit 20, The alarm issuing unit 30 is operated so as to allow the operator to quickly move through the danger alert if there is a risk of collapse and to take subsequent measures to prevent collapse.

The alarm notification is issued when the central processing unit 20 issues an individual danger warning and comprehensive risk warning or when the central processing unit 20 issues only a comprehensive risk alert and the corresponding data relay unit 13 sends an individual unauthorized alarm And the like.

At this time, the connection method of the load cell 11 installed in each vertical frame S1, the data relay unit 13, the plurality of data collecting units 10, and the central processing unit 20 may be wired, wireless, Method can be considered,

The load cell 11 and the data relay unit 13 are connected to each other by wire to prevent malfunction due to rapid processing of load data measured by the load cell 11 and interference between wireless communication networks, That is, each data repeater 13 and the central processing unit 20 are wirelessly connected.

Therefore, the present invention can efficiently manage the load by using a combination of wired and wireless, and can be conveniently installed and constructed.

As shown in [A] of FIG. 2, the load cell 11 is provided with a notch 11a corresponding to a sectional shape of the vertical frame S1, which is recessed downward on the upper surface of the body 11A, A sensor (not shown) for detecting a load is incorporated in the lower portion of the inner portion 11a to individually measure a load transmitted to the vertical frame S1.

Although the figure shows a load cell 11 having a circular notch portion 11a as an example, the right interpretation of the present invention should not be limited by the shape and size of the notch portion 11a.

The load cell 11 is provided with a terminal portion 11b for wired connection with the data repeater 13 on one side of the body 11A and a cable 12 for wire connection may be integrally formed with the load cell 11, As shown in FIG.

The load measurement range of the sensor may vary depending on the size and type of scaffold installed (for example, 0 to 3 tons).

Since the pair of structures composed of the plurality of data collecting units 10, that is, the load cell 11 and the data repeater 13 are separately installed for each vertical frame S1, the load cell 11, the cable 12 ) And the data relay device 13 are easily stored and transported, it is important that the scaffold load detection system can be installed easily and quickly.

Accordingly, the data collecting unit 10 of the present invention solves the above-described problem by configuring the data relay unit 13 as a housing that can carry and store the other configurations of the data collecting unit 10. [

The first housing 14 borrowed by the data repeater 13 of the data collecting unit 10 includes a first accommodating portion 14A in which the load cell 11 is stored, And a control module (not shown) connected to the load cell 11 to process and transmit the measured load data.

The first enclosure 14 is formed in a box shape, and the lid 15 opens and closes the upper opening at the upper portion. A packing member (not shown) is provided around the lid 15 to primarily ensure the airtightness of the inside and the outside of the first enclosure 14.

The first housing 14 is further provided with fastening means 150 for opening and closing the lid 15. The fastening means includes a plurality of clamping members 151 hinged to the outer surface of the upper side of the side wall of the housing,

And an engaging member 156 coupled to the lower outer surface of the lid 15 and protruding to fasten the respective clamping members 151.

The clamping member 151 and the engaging member 156 may be reversely coupled to the side wall of the first enclosure 14 and the cover 15 unlike the first embodiment.

The fastening means 150 may be applied to the second housing 22 and the third housing 32, which will be described later.

The first housing 14 has an inner space divided by a partition 17 so that one side is used as a first accommodating portion 14A in which the load cell 11 and the cable 12 are stored and a control module And serves as a mounting portion 14B to be embedded.

A bolt-coupled inner cover 18 is provided on the upper portion of the mounting portion 14B to shield the mounting portion 14B separately from the cover 15. [ The inner cover 18 is provided with an antenna 19 connected to the control module and wirelessly connected to the central processing unit 20.

A terminal portion 14b to which a cable 12 for wire connection between the control module and the load cell 11 is coupled, a power button 14c, a weight limiter 14b, etc., connected to the mounting portion 14B, And a display unit 14e for allowing the user to confirm the collected load data.

A power supply unit (not shown) for supplying power to the load cell 11 separated from the first accommodating unit 14A and the attaching unit 14B is provided under the inner space of the first housing 14, Etc.) are further embedded. The power supply part is connected to the terminal part of the side wall, and power is supplied to the load cell 11 through the cable.

Therefore, the present invention can easily and conveniently store and transport the components of the data collecting unit 10 by providing the function of the data relay unit 13 to the first enclosure 14, The operation can also be performed easily and conveniently.

On the other hand, a plurality of data collecting units 10 are provided corresponding to each vertical frame S1, but the central processing unit 20 has only one configuration for information processing and analysis.

The central processing unit 20 may be an information processing device such as a computer provided in the middle control room. However, it may be possible to reuse the specific property of the construction site and the scaffold load sensing system used after the completion of construction, It is more preferable that the portable information processing terminal 21 such as a notebook computer is used as the central processing unit 20 as shown in FIG. In the drawings, the notebook is shown as a representative for convenience of explanation, but it can be further utilized as a smart phone, a tablet PC, and the like.

Since the portable information processing terminal 21 may be installed in an external environment, the central processing unit 20 may be provided with a second receiving portion 22A for storing the terminal 21, 2 enclosure (22).

The second housing 22 is further provided with a power supply unit (not shown) (for example, a rechargeable battery) capable of supplying power to the terminal 21, and a cable for connection between the terminal and the power supply unit have.

3, the second housing 22 is housed in the second housing portion 22A, and the lid 25, which houses the terminal 21 and covers the upper opening, is hinged to the second housing portion 22A, Respectively.

The second housing (22) is further provided with a support plate (23) detachably attached to the upper opening of the second accommodating portion (22A). When the terminal 21 is stored in the second accommodating portion 22A, the support plate 23 together with the cover 25 prevents the terminal 21 from being exposed to external environmental factors, and when the scaffold load sensing system is operating The terminal 21 is installed on the upper surface of the base plate 23 so that the terminal 21 can be easily used by the user.

On the upper surface of the receiving plate 23, a terminal fixing means 24 is further provided. The fixing means 24 is composed of fixing pieces 24A of the receiving plate 23 so that the front, rear, left and right sides of the terminal 21 can be pressed and fixed.

When the terminal 21 is used as a notebook, various sizes of notebooks are manufactured according to makers and models, so that the fixing pieces 24A are changed in position from the upper surface of the receiving plate 23 through position adjusting means So that all of the terminals 21 can be fixed regardless of the size of the terminal 21.

The alarm issuing unit 30 includes an alarm issuing unit 31 installed on one of the upper scaffolds of the scaffold K so that the operator can easily recognize when a danger alarm is issued. The installation place of the issuing machine may be variable.

The alarm issuing unit 31 is connected to the control module of the data collecting unit 10 and the portable information processing terminal 21 of the central processing unit 20 wirelessly.

When the control module or the terminal 21 transmits a critical alarm signal, the alarm issuing device 31 operates a warning lamp to emit an alarm signal together with a siren signal .

The alarm issuing unit 30 also includes a third housing 32 for storing the alarm issuing unit 31 so that storage and transportation can be easily performed.

The third enclosure 32 also includes a third accommodating portion 31A for accommodating the alarm issuing device 31 and a lid 35 for opening and closing the upper opening of the third accommodating portion 31A.

The third enclosure 32 also has a built-in power supply unit (not shown) therein so that the third enclosure 32 is connected to the alarm issuing unit 31 via a cable so that power is always supplied.

The third enclosure 32 is provided with an antenna 39 for wireless communication and the alarm signal generator 31 and the third enclosure 32 are connected to each other via a cable to connect the information collecting unit 10 and the central processing unit 20 is preferably established.

The data collecting unit 10 of the present invention is installed under the vertical frame S1 of the scaffold and is installed in the first enclosure 14 used as the load cell 11 and the data repeater 13, ) Is likely to be exposed to various external environments, and there is a risk of malfunction or malfunction if exposed to rain, snow, or other moisture.

In particular, since the load cell 11 directly mounted with the lower end of the vertical frame S1 of the scaffold is embedded in the body 11A, it is easy to implement the waterproof structure of the body 11A itself, And less risk of malfunctions,

Since the first housing 14 has a built-in control module for analyzing and processing the collected load data, it is very important that the waterproof property of the control module protects it from moisture.

To this end, the first housing 14 is primarily waterproofed through a packing member provided on the lid 15.

As shown in FIGS. 2 and 9, the first enclosure 14 is bolted to the support portion 14f formed on the side wall of the first enclosure 14 while the cover 18 is staggered.

Further, a separate packing member may be provided between the cover 18 and the receiving portion 14f to ensure waterproofness. However, since the first enclosure 14 is installed outside the field as a data relay, It is not easy to ensure complete waterproofing by using only the ordinary packing member. In particular, when the first enclosure 14 is left outside in a state in which the lid is opened, it is necessary to secure more waterproof property.

Accordingly, the waterproofing means 180 is inserted between the cover 18 covering the mounting portion where the control module is installed and the side wall of the first housing 14 to improve waterproofness.

The waterproofing means 180 for sealing the clearance between the cover 18 and the receiving portion 14f (see FIG. 2) of the side wall of the first housing 14

An upper fitting protrusion 181 protruding downward from a lower contact surface formed along the rim of the cover 18,

A lower fitting protrusion 182 protruding upward from an upper contact surface connected inwardly from the receiving portion 14f and slidably engaged with the upper fitting protrusion 181,

The middle portion has a zigzag structure so as to be disposed between the upper fitting projections 181 and the lower fitting projections 182 and air is filled in the middle portion so that the upper fitting projections 181 and the lower fitting projections 182 are engaged with each other. A pair of abutting pads 183 each of which is swollen on both sides while the inner air is pushed to the opposite side edges and closely contact the upper fitting protrusion 181 and the lower fitting protrusion 182,

The cover 18 and the receiving portion 14f are integrally formed with the cover 18 and the receiving portion 14f so that the edge of the contacting pad 183, which is protruded upward and downward from the inner surface of the cover 18 and the receiving portion 14f, And a support portion 184 for supporting the outer side of the support portion 183.

The inner side of the contact pad 183 is connected to both the upper and lower portions with reference to the drawing to cover and seal the coupling gap between the upper fitting projections 181 and the lower fitting projections 182 and the outer side is expanded in the accommodated narrow space Thereby sealing the coupling gap.

When the upper fitting protrusions 181 and the lower fitting protrusions 182 are fitted and press-contacted, the inner air presses the contact pressing force Both sides move to both sides that do not support,

Both the expanded sides are tightly attached to the cover 18 and the receiving portion 14f while covering the clearance between the upper fitting projection 181 and the lower fitting projection 182 so that the outer moisture To prevent penetration.

Although not shown in the drawing, the waterproofing means 180 may be provided to the second and third enclosures 22 and 32 so as to ensure the airtightness of the respective enclosures by adding a configuration corresponding to the cover 18 Can be applied.

While the present invention has been described with reference to the accompanying drawings, it should be understood that various changes, substitutions and alterations can be made by those skilled in the art without departing from the spirit and scope of the invention. Should be construed as falling within the scope of protection of the present invention.

K: Generator furnace
S: Scaffold S1: Vertical frame
S2: Scaffolding
10: Data collecting unit 11: Load cell
13: data repeater 14: first enclosure
20: central processing unit 21: portable information processing terminal
22: Second enclosure
30: alarm issuing section 31: alarm issuing section
32: Third enclosure

Claims (4)

A plurality of data collecting units (10) installed below the vertical frame (S1) and including a load cell (11) for sensing loads in real time;
A central processing unit 20 for receiving and collecting the load data collected by the data collecting unit 10; And
And an alarm issuing unit 30 operating in conjunction with the data collecting unit 10 or the central processing unit 20 or both of them,
When the load data measured by each load cell 11 deviates from the load limit value of the previously stored individual vertical frame S1 or when the load data collected by the central processing unit 20 exceeds the load limit value of the entire pre- The command section 30 is operated to generate a danger warning,
The data collecting unit 10 includes a first accommodating unit 14A for storing the load cell 11 and a control unit connected to the load cell 11 to process and transmit the measured load data, (14)
The first enclosure 14 further includes a cover 18 coupled to the side wall and a waterproof means 180 sealing the clearance between the cover 18 and the receiving portion 14f of the side wall,
The waterproof means 180 includes an upper fitting protrusion 181 protruding downward from a lower contact surface formed along the rim of the cover 18,
A lower fitting protrusion 182 protruding upward from an upper contact surface connected inwardly from the receiving portion 14f and slidably engaged with the upper fitting protrusion 181,
The middle portion has a zigzag structure so as to be disposed between the upper fitting projections 181 and the lower fitting projections 182 and air is filled in the middle portion so that the upper fitting projections 181 and the lower fitting projections 182 are engaged with each other. A pair of abutting pads 183 each of which is swollen on both sides while the inner air is pushed to the opposite side edges and closely contact the upper fitting protrusion 181 and the lower fitting protrusion 182,
The cover 18 and the receiving portion 14f are integrally formed with the cover 18 and the receiving portion 14f so that the edge of the contacting pad 183, which is protruded upward and downward from the inner surface of the cover 18 and the receiving portion 14f, And a support portion (184) for supporting an outer side of the inner wall (183). The method according to claim 1,
Wherein the load cell 11 includes a notched portion 11a on which a lower end of the vertical frame S1 is placed and a sensor built in the lower portion of the notched portion 11a to sense a load. Detection system. The method according to claim 1,
The central processing unit 20 comprises a portable information processing terminal 21,
And a second housing (22) having a second accommodating portion (22A) for storing the terminal (21) and a power supply portion for supplying power to the terminal (21) . 4. The method according to any one of claims 1 to 3,
The alarm system according to claim 1, wherein the alarm notification unit (30) comprises an alarm notification unit (31) and a third housing (32) in which the alarm notification unit (31) is stored.

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