KR102331266B1 - Wall system for variable type - Google Patents

Abstract

The present invention provides an automatically controlled earthquake-proof wall including an upper fixing part, prefabricated wall parts inserted to the upper fixing part to form a wall, support poles, finishing plates, springs, a vibration processing module for measuring and further absorbing vibration flowing through the earthquake-proof wall, a moisture removing module for removing moisture from the inside of the prefabricated wall parts, and a control unit for controlling data signals from the above components.

Description

Self-adjusting seismic wall {Wall system for variable type}

The present invention relates to an automatic adjustment earthquake-resistant wall, and more particularly, to absorb and measure the vibration flowing through the upper fixing part and the assembled wall part inserted thereto to form a wall, a support pole, a finishing plate, a spring, and an earthquake-resistant wall It relates to a vibration processing module for, a moisture removal module for removing moisture inside an assembly wall, and an automatic adjustment earthquake-resistant wall equipped with a control unit for controlling their data signals.

In general, a wall is widely used to divide various indoor spaces such as a building, for example, a school, an office, an exhibition hall, a rest room, a cultural space, a residential space, and a work place, or to effectively construct a space for office work.

In addition, the wet wall method, which is constructed by stacking blocks or bricks, and the dry wall method, which is constructed with partitions or panels, are mainly applied.

In particular, unlike wet walls by a wet construction method, which is constructed by stacking blocks or bricks, drywall is lightweight and can be installed in a state that does not burden the building, and has the advantages of simple construction, rapid operation and low cost of construction.

In terms of use, such drywall is installed only up to a predetermined height from the floor so that it can be improved not only in terms of appearance, ease of installation and dismantling, but also in dividing the entire space into several spaces to improve the environment for residential and office environments. Or it is installed so as to reach from floor to ceiling.

In the conventional drywall, as shown in FIG. 1, after the ceiling and floor slab concrete (1) (2) is constructed, the gypsum board drywall (3) is constructed, and then the ceiling finishing member (4) and the floor heating Mortar (5) is carried out in the order of construction.

On the other hand, durability and variability are required according to the lifespan of apartment houses and the diversification of family members.

Construction companies offer options to tenants by installing or not installing walls for some walls when selling apartment houses, and tenants install or do not install walls according to various options.

However, the option presented to the occupants is to install or not install the wall at the time of construction, and even if you want to change the already installed wall after moving in, as shown in FIG. It is buried in the heating mortar 5, so it is very difficult to actually change (install or remove) the wall.

In addition, in the general gypsum board wall system as described above, since the floor heating mortar (5) construction is performed after the wall is installed, the wet and dry construction methods are mixed, and mold, etc., is generated in the gypsum board dry wall (3). have.

There are also cases where drywall is installed after underfloor heating mortar construction is performed.

In this case, by fixing the lower runner using a fixing means such as a nail or a tack, the floor finishing material may be damaged, and more seriously, the heating pipe is damaged by the sharp end of the fixing means such as a nail or a nail. There is a problem, and because of this, there is a difficulty in construction.

In addition, after the wall is demolished, a small-scale repair work to fill in the nail marks left in the removed place or, if the floor finish material is severely damaged, a large-scale repair work must be performed after tearing off the damaged area. There is this.

In addition, the conventional drywall has a disadvantage in that it is necessary to prepare walls of various standards according to the height from the floor to the ceiling.

Accordingly, in order to solve this problem, a drywall that can be adjusted in height according to the height from the floor to the ceiling has been proposed.

However, the conventional wall having a height adjustment structure adopts a method of adjusting the height of the wall by turning a height adjustment screw provided in the lower part.

This has a problem in that it is difficult to adjust the height of the wall because it has to be carried out while carrying the weight of the wall having a relatively heavy weight.

However, since the above-mentioned conventional drywall is formed with a high weight, there is a problem in that it is still difficult to install, remove, change, etc., especially for people who are somewhat weaker than men, such as women.

Accordingly, there is a problem in that when you want to install, remove, or change the location of the conventional drywall, you have to ask experts who specialize in it.

In addition, the conventional drywall has a problem in that it has a limitation in use that people with small physical conditions, that is, short height, cannot perform the work as the level adjusting unit for performing the height adjustment is configured on the upper part.

The present invention has been devised to solve the above problems, and an object of the present invention is to form a wall as it is fixed between an upper fixing part including a cover mold fixed to a ceiling and having an accommodating space formed therein, and the ground. It is to provide a self-adjusting earthquake-resistant wall provided with an assembled wall unit.

Another object of the present invention is to provide a self-adjusting earthquake-resistant wall equipped with a support pole, a finishing plate for finishing both sides of the support pole, and a spring at the top of the support pole.

Another object of the present invention is to provide an automatically adjustable seismic wall equipped with a vibration processing module for absorbing and measuring vibrations flowing along the seismic wall.

Another object of the present invention is to provide a self-adjusting seismic wall equipped with a moisture removal module for removing moisture generated inside the assembly wall.

Another object of the present invention is to provide an automatically adjustable seismic wall equipped with a control unit for controlling the processing signal of the vibration processing module and the moisture removal module.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The self-adjusting seismic wall according to an embodiment of the present invention for solving the above problems is inserted into the receiving space of the upper fixing part and the upper fixing part including a cover mold fixed to the ceiling and having an accommodating space formed therein, and the It may include a plurality of assembly wall parts configured in an assembling manner so that the wall is formed as it is fixed between the upper fixing part and the ground.

In one embodiment, the assembly wall part, a plurality of support poles configured at both ends, is configured between the plurality of support poles, and a finishing plate for finishing both surfaces of the support pole and is configured on the upper end of the support pole, , It may include a spring for supporting the assembly wall portion to be firmly fixed to the ground by the elastic force and to have earthquake resistance by the elastic force.

In one embodiment, the self-adjusting seismic wall is a vibration processing module installed on the inner wall surface of the self-adjusting seismic wall to further absorb and measure vibrations from the outside flowing along the seismic wall, inside the assembly wall part. It may further include a moisture removal module installed to prevent decay due to moisture generated inside the assembly wall unit by an external environment, and a control unit for controlling information processing signals of the vibration processing module and the moisture removal module.

In one embodiment, the vibration processing module includes a measuring unit that detects vibration and frequency generated in the self-adjusting seismic wall, a body surrounding the measuring unit and including the measuring unit therein, and the vibration frequency measured by the measuring unit. A display unit for indicating the size on the outer peripheral surface of the assembly wall part, a shaft that is fastened to and fixed to the main body and can be adjusted in length to a certain height, a base that is horizontally fastened to the shaft to support the main body, and the shaft and the base. The government, a connecting member that is bound to and fixed to the base, a housing that is fastened to the connecting member so that the pad part can be bound, a seating groove provided on the inner surface of the housing for binding and fixing to the pad part locking protrusion, and in the housing It may include a pad portion that is fixed to prevent vibration generated in the self-adjusting earthquake-resistant wall.

In an embodiment, the measuring unit may include a vibrating body for sensing vibration, a flow pipe sealing the vibrating body, and a vibration measuring unit measuring vibration transmitted through the flow pipe.

In one embodiment, the main body, but having a cylindrical or cylindrical or rectangular shape, one surface is formed with a flat cover, and may further include a network characterized by wireless communication connected to the control unit.

In one embodiment, the base includes a feature that one surface has a cylindrical, cylindrical or rectangular shape corresponding to the shape of the body, and a locking groove for binding the locking protrusion is formed on the inner peripheral surface of the seating groove, and the The pad part includes a pad having a plurality of absorbent materials inserted therein and fastened to the seating groove formed in the housing, and the pad is formed in a semicircular shape or a rectangular shape with rounded corners, and the housing is seated on the upper part. It may include a feature of forming a shape in which a plurality of locking projections can be fastened to the locking groove formed in the groove.

In one embodiment, the moisture removal module, a humidity sensor installed inside the assembly wall unit to measure the humidity therein, and a heater installed inside the assembly wall unit to generate warm wind under the control of the control unit. may include

In one embodiment, the humidity sensor is installed on the upper surface of the humidity sensor, and is formed to extend on the transmission plate and the transmission plate for transmitting information about the humidity measured by the humidity sensor, and is measured by the humidity sensor with the control unit and a line unit for transmitting information about a humidity, and the heater may include a fan that rotates to generate a warm wind under the control of the control unit toward the assembly wall unit.

In an embodiment, the control unit generates earthquake-resistance-related information using the magnitude of the vibration sensed by the measurement unit, and transmits it to an external server through the network. Based on the humidity detection result measured by the humidity sensor As a result, it may include a feature for controlling the operation of the fan and the heater.

According to the present invention, the upper fixing part and the assembly wall part inserted therein to form the wall, the support pole, the finishing plate, the spring, the vibration processing module for further absorbing and measuring the vibrations flowing through the earthquake-resistant wall, the inside of the assembly wall part A moisture removal module for removing moisture and a control unit for controlling a data signal thereof are provided. The effect according to the present invention is not limited by the contents exemplified above, and more various effects are included in the present invention.

1 shows a schematic cross-sectional view of a conventional gypsum board drywall.
2 is a cross-sectional view schematically showing a drywall showing another example of the prior art.
Figure 3 shows a schematic perspective view of the self-adjusting seismic wall according to the present invention.
4 is an exploded perspective view of a part of the assembly wall part according to the present invention.
5 is a schematic cross-sectional view of the self-adjusting seismic wall according to the present invention.
6 is a perspective view of an assembled wall part according to the present invention.
7 is a cross-sectional view of the assembled wall part according to the present invention.
8 is a detailed view of the configuration of the lower end of the vibration processing module according to the present invention.
9 is a detailed view of the configuration of the upper end of the vibration processing module according to the present invention.
10 shows an embodiment of a vibration processing module according to the present invention.
11 shows an embodiment of a moisture removal module according to the present invention.
12 shows a partial configuration of a moisture removal module according to the present invention.
13 shows the connection relationship of the control unit of the self-adjusting seismic wall according to the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the accompanying drawings. The embodiments described herein may be variously modified. Certain embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the accompanying drawings are only provided to facilitate understanding of the various embodiments. Therefore, the technical idea is not limited by the specific embodiments disclosed in the accompanying drawings, and it should be understood to include all equivalents or substitutes included in the spirit and scope of the invention.

Terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but these components are not limited by the above-mentioned terms. The above terminology is used only for the purpose of distinguishing one component from another component.

In this specification, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof. When an element is referred to as being “connected” or “connected” to another element, it is understood that it may be directly connected or connected to the other element, but other elements may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

Meanwhile, as used herein, a “module” or “unit” for a component performs at least one function or operation. And “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. In addition, a plurality of “modules” or a plurality of “units” other than a “module” or “unit” to be performed in specific hardware or to be executed in at least one processor may be integrated into at least one module. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be abbreviated or omitted.

Figure 3 shows a schematic perspective view of the self-adjusting seismic wall according to the present invention.

The self-adjusting earthquake-resistant wall of the present invention may include an upper fixing part 10 and an assembled wall part 20 as shown in FIGS. 3 to 7 .

In addition, the self-adjusting earthquake-resistant wall of the present invention may further include a vibration treatment module 100 , a moisture removal module 300 , and a control unit 170 .

The upper fixing part 10 has one end fixed to the ceiling, etc., and may perform a function of supporting the upper end of the assembly wall part 20 so that it can be stably fixed.

In addition, the upper fixing part 10 may be formed of a material such as transparent, opaque, or translucent.

This may be provided in various forms according to the user's request for the interior of the room.

The upper fixing part 10 may include a cover mold 30 and a finishing mold 50 .

The cover mold 30 may be fixed to the ceiling or the like, and perform a function of supporting the upper end of the assembly wall unit 20 .

The cover mold 30 includes an accommodating space 31 formed therein to a predetermined depth and into which a portion of the upper end of the assembly wall part 20 is inserted.

The accommodating space 31 is formed to a predetermined depth, so that a portion of the upper end of the assembly wall part 20 can be accommodated, so that a beautiful finish is made.

In addition, the accommodating space 31 may include a cover function that prevents foreign substances from penetrating into the assembly wall unit 20, so that even if dismantling is made by moving or demolition, neat demolition work can be performed. have.

The upper fixing part 10 may include a finishing mold 50 configured at the lower end of the cover mold 30 to prevent the lower part from being damaged.

The finishing mold 50 is configured at each of the lower ends of the cover mold 30 to prevent damage caused by bumping or the like when inserting the assembly wall part 20 into the inside of the cover mold 30 to form a dry wall. do.

The finishing mold 50 is configured in a stepped shape with the cover mold 30 to obtain a beautiful design.

The finishing mold 50 is made of a material different from that of the cover mold 30 , thereby improving interior sensibility due to a sense of heterogeneity.

For example, the finishing mold may be made of a material for protecting the cover mold and improving design, or rubber, silicone, or synthetic resin.

Without being limited thereto, the finishing mold may be made of aluminum or stainless steel to improve the design.

The finishing mold 50 may be formed with a step difference so that it can be stably seated and maintained at the lower end of the cover mold 30 .

Also, the finishing mold 50 may be formed along the longitudinal direction of the cover mold 30 .

Without this limitation, a plurality of finishing molds may be configured to be intermittently spaced apart from each other at regular intervals along the longitudinal direction of the cover mold.

The assembly wall part 20 may be inserted into the receiving space 31 of the upper fixing part 10 and configured in an assembly manner so that the wall is formed as it is fixed between the upper fixing part and the ground.

4 is an exploded perspective view of a part of the assembly wall part according to the present invention.

The assembly wall unit 20 may include a support pole 60 , a mounting bracket 70 , a finish plate 80 , and a spring 90 .

The support pole 60 is configured to be spaced apart from each other by a predetermined interval at both ends, and provides support to perform a column function.

The support pole 60 is preferably formed of aluminum to reduce weight and to have corrosion resistance.

In addition, the support pole 60 is configured in a hollow tube shape with an empty inside, and is formed in a rectangular shape.

The seating bracket 70 is configured at one end of the support pole 60 and functions to support the spring 90 so that it can be stably seated.

5 is a schematic cross-sectional view of the self-adjusting seismic wall according to the present invention.

The seating bracket 70 may include a seating space 71 that is recessed to a predetermined depth on the inside to allow the spring 90 to be seated therein.

The seating space 71 is recessed to have a predetermined depth at the upper end of the seating bracket 70 to form a space in which the spring 90 is stably seated.

In addition, the seating bracket 70 has a through hole 72 configured to support one end of the spring 90 seated in the seating space 71 .

The through hole 72 is formed in a predetermined size on the bottom surface of the seating space 71, and the lower end of the spring 90 is fixed in the inserted state, thereby preventing the loss of the spring 90 seated in the seating space 71. to prevent

In this case, the through hole 72 may be omitted, and after the spring 90 is seated in the seating space 71 , the lower end of the spring 90 may be integrated with the seating bracket 70 by welding or the like.

It is not limited thereto, and any configuration or structure that allows the spring 90 to be stably fixed to the seating space 71 may be used.

For example, it may be fixed through a fixing means such as a direct bolt or pin, and in some cases, the spring may be used without separately fixing the spring in the seating space.

6 is a perspective view of an assembled wall part according to the present invention.

The lower end of the seating bracket 70 is inserted into the support pole 60 to a certain depth, so as to maintain a state fixed to the support pole 60 .

The mounting bracket 70 is integrated by a fusion method such as welding or fixed with a fixing means such as a direct connection bolt.

It is not limited to this, and any configuration or structure that allows the lower part of the mounting bracket to be stably fixed to the upper end of the support pole can be used.

The finishing plate 80 is configured between the plurality of support poles 60, and performs a function of finishing both surfaces of the support poles.

The finishing plate 80 is formed of a lightweight plywood with a thickness of 3 to 8 mm, but preferably a thickness of 5 mm.

This can be set differently depending on the purpose of use or the place of installation, and in addition to plywood, it can be replaced with a lightweight iron plate, synthetic resin panel, or aluminum.

The finishing plate 80 is fixed to the support pole 60 with a fixing means such as a direct connection bolt.

Any means capable of stably fixing the finishing plate to the support pole, such as an adhesive or clamp, is sufficient, but not limited thereto.

7 is a cross-sectional view of the assembled wall part according to the present invention.

When the finish plate 80 is fixed to the support pole 60, one end is located in the middle of the support pole 60, and the other end is conversely protruded from the support pole 60 by a certain length, and the finish plate 80 An insertion space 81 is formed between the

That is, one end of the support pole protrudes to have a certain length, that is, as long as the width at which the support pole is exposed, while the other end completely surrounds the support pole, so that the middle part of the end plate is not completely covered. to form an insertion space between the

Accordingly, when assembling the neighboring assembly wall parts 20 to each other, the support pole 60 exposed in one assembly wall part 20 is an insertion space 81 configured in the other assembly wall part 20 . By being inserted into the wall is formed by a plurality of assembly wall parts (20).

In this case, the finishing plate 80 is preferably formed at the same or similar height as the support pole 60 .

The spring 90 is configured at the upper end of the support pole 60, so that the assembly wall portion 20 is firmly fixed to the ground by an elastic force and can be supported to have earthquake resistance by the elastic force.

The spring 90 is configured such that the lower end is seated in the seating space 71 of the seating bracket 70 , and the upper end is exposed at a predetermined height from the seating bracket 70 .

Accordingly, when the upper end of the assembly wall unit 20 is inserted into the upper fixing unit 10 , the spring 90 whose upper end is exposed in the mounting bracket 70 of the assembled wall unit 20 is assembled with the upper fixing unit 10 . While maintaining the compressed state by the height deviation of the wall part 20, the assembled wall part 20 is supported to be firmly fixed to the ground by the elastic force.

Therefore, regardless of the flatness of the ground, the installation of the assembly wall part 20, the upper end of which is supported by the upper fixing part 10, is easily made.

In addition, by the elastic action characteristics of the spring 90, the effect of securing seismic resistance to the drywall can be obtained by absorbing action from the spring even when the inside or outside of the building, for example, earthquake, vibration, or external shock acts. have.

The spring 90 may be configured as a tension spring or a compression spring.

The installation principle of the above configuration will be described in detail as follows.

First, the upper fixing part is fixed to the ceiling.

The upper fixing part is fixed with a fixing means such as a nail, a direct screw, or a hook.

Alternatively, it may be fixed by constructing a fixing bracket between the ceiling and the upper fixing part.

When the fixing of the upper fixing part to the ceiling is completed, the upper end of the assembly wall part of the sheet is inserted so that it can be inserted into the receiving space of the upper fixing part.

Since the upper end of the spring is exposed to the upper end of the inserted assembly wall portion, an elastic force acts between the upper fixing portion and the assembled wall portion by the spring, so that the assembly wall portion is It is fixed in an upright state.

Then, as described above, the other assembled wall part is inserted into the upper fixing part.

Then, the other inserted assembly wall part is transferred to the already inserted assembly wall part side so that a plurality of assembly wall parts are assembled with each other.

That is, the insertion space formed by the finish plate protruding a certain length based on the support pole is formed at one end of the previously inserted assembly wall part, and at one end of the other assembly wall part, the finish plate is located only in part, and the support pole exposed by a certain width is Consists of.

Therefore, by inserting the exposed support pole of the other assembly wall part into the insertion space of the previously inserted assembly wall part, the plurality of assembly wall parts are fixed to each other by assembling.

Referring to FIG. 11 , the self-adjusting seismic wall is a vibration treatment module 100 installed on the inner wall surface of the self-adjusting seismic wall to further absorb and measure vibrations from the outside flowing along the seismic wall, the assembly wall Controls the information processing signal of the moisture removal module 300 and the vibration processing module and the moisture removal module installed inside the unit to prevent mold or dew condensation from occurring due to moisture generated inside the assembly wall part due to the external environment It may further include a control unit 170 that does.

8 is a detailed view of the configuration of the lower end of the vibration processing module according to the present invention, and FIG. 9 is a detailed view of the configuration of the upper portion of the vibration processing module according to the present invention.

The vibration processing module includes a measuring unit 110 , a main body 101 , a display unit 130 , a shaft 182 , a base 181 , a fixing unit 180 , a connecting member 211 , a housing 212 , and a seating unit. It may include a groove 213 and a pad part 220 .

The measurement unit 110 may be installed inside the main body to detect vibrations and frequencies generated in the self-adjusting earthquake-resistant wall.

The measuring unit 110 may include a vibrating body 111 , a flow pipe 112 , and a vibration measuring unit 114 .

The vibrating body 111 may sense external vibration as a spring-shaped, winding iron rod.

The flow tube 112 has a cylindrical shape and seals the vibrating body 111, and includes a feature of amplifying the vibration sensed by the vibrating body.

The vibration measuring unit 114 may measure the vibration amplified by the flow tube 112 .

The vibration measuring unit 114 may be integrally formed on the end of the vibrating body 111 or the bottom surface of the flow pipe 112 .

The body 101 has a shape that surrounds the measurement unit 110 to protect it from the outside, and may have a cylindrical, cylindrical or rectangular shape, and may be formed of a material that can strongly withstand external impact.

The main body 101 is formed with a cover 102 having a flat surface at the bottom, so that the exterior can be more strongly protected.

In addition, the main body 101 may further include a network 120 characterized by wireless communication connected to the control unit 170 , and may transmit the vibration frequency measured by the measurement unit 110 to the control unit through the network.

The display unit 130 may receive the frequency magnitude of the vibration measured by the measurement unit 110 through the network 120 and display it on the outer peripheral surface of the assembly wall unit 20 .

The fixing unit 180 may include a shaft 182 and a base 181 .

The shaft 182 is fastened to and fixed to the upper end of the main body 101 , and the length can be adjusted to a certain height, so that the overall length of the vibration processing module can be adjusted according to the inner width of the assembly wall unit 20 .

The base 181 may be horizontally fastened to the shaft 182 to support the body 101 .

The base 181, like the main body 101, may have a cylindrical, cylindrical or rectangular shape, and is made of a material that can withstand external shock or vibration.

The connecting member 211 may be fastened to and fixed to a plurality of grooves (not shown) formed on the upper surface of the base 181 .

At this time, the number of connection members is not limited, and it is irrelevant as long as the number can sustain strong coupling between the base 181 and the housing 212 .

The housing 212 may be fastened to the connection member 211 to form an integral body with the base 181 and bind the pad part 220 .

The seating groove 213 is provided on the inner surface of the housing 212 so that the locking protrusion of the pad part 220 and the locking groove 213a are bound to be strongly fixed.

The pad part 220 is fixed to the housing 212 through the locking protrusion 223 , and an absorber 222 is provided on the pad 221 to absorb and prevent vibrations generated from the self-adjusting seismic wall.

The pad 221 is formed in a semicircular shape or a rectangular shape with rounded corners, and a plurality of locking projections 223 can be fastened to the locking grooves 213a formed in the seating grooves 213 of the housing 212 at the upper portion. formed to be

10 shows an embodiment of a vibration processing module according to the present invention.

The operating principle of the above configuration will be described in detail as follows.

When the vibration flowing through the assembly wall part occurs, the vibrating body senses the vibration inside the main body, amplifies it in the flow tube, and measures the vibration frequency in the vibration measuring unit.

Thereafter, the magnitude of the frequency measured by the display unit is displayed on the small display through the network, and the vibration frequency information is transmitted to the control unit.

The vibration absorbed through the body flows to the pad part along the shaft, and the absorbent material is reabsorbed and extinguished.

The operating principle of the above configuration is in addition to the series of operating principles such as the cover mold, the finishing mold, and the spring mentioned above, it is possible to effectively absorb the vibration that flows throughout the assembly wall in two steps, thereby enhancing the vibration reduction effect of the present invention. do it

11 shows an embodiment of the moisture removal module according to the present invention, Figure 12 shows a partial configuration of the moisture removal module according to the present invention.

The humidity removal module may include a humidity sensor 310 and a heater 350 .

Humidity sensor 310 is installed on the upper surface of the humidity sensor, the transmission plate 320 for transmitting information about the humidity measured by the humidity sensor, is formed extending on the transmission plate, the humidity sensor to the controller 170 It may include a line unit 330 for transmitting information about the measured humidity.

The heater 350 may include a fan 340 that rotates toward the assembly wall unit to generate warm wind under the control of the controller 170 .

The operating principle of the above configuration will be described in detail as follows.

The humidity sensor constantly measures the humidity inside the assembly wall, converts the measured humidity information into data, and processes the information on the transmission plate so that the information can be transmitted.

The line unit transmits the humidity information received by the transmission plate to the control unit, and when the humidity is higher than the average value, the control unit operates a fan and a heater to generate warm wind to cause a convection phenomenon to control the humidity.

13 shows the connection relationship of the control unit of the self-adjusting seismic wall according to the present invention.

The control unit 170 generates seismic-resistance-related information using the magnitude of the vibration detected by the measurement unit 110 , and transmits it to an external server through the network 120 , and the humidity detection result measured by the humidity sensor 310 . It may include a feature for controlling the operation of the fan and heater based on the

Although preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications are possible by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

1: Ceiling concrete
2: Concrete floor slab
3: Gypsum board drywall
4: Ceiling finishing member
5: Floor heating mortar
10: upper fixed part
20: assembly wall part
30: cover mold
50: finish mold
60: support pole
70: mounting bracket
80: finish plate
90: spring
100: vibration processing module
110: measurement unit
120: network
130: display unit
170: control unit
180: fixed part
210: coupling part
220: pad part
300: moisture removal module
310: humidity sensor
320: transfer plate

Claims (2)

an upper fixing part fixed to the ceiling and including a cover mold having an accommodating space formed therein; and
a plurality of assembly wall parts inserted into the receiving space of the upper fixing part and configured in an assembling manner so that a wall is formed as it is fixed between the upper fixing part and the ground;
In the self-adjusting seismic wall comprising a,
The assembly wall part,
a plurality of support poles configured at each of both ends;
a finishing plate configured between the plurality of support poles and finishing both surfaces of the support poles; and
a spring configured on the upper end of the support pole, so that the assembly wall part is firmly fixed to the ground by an elastic force, and a spring for supporting it to have seismic resistance by an elastic force;
including,
The self-adjusting seismic wall,
a vibration processing module installed on the inner wall surface of the self-adjusting earthquake-resistant wall to further absorb and measure vibrations from the outside flowing along the earthquake-resistant wall;
a moisture removal module installed inside the assembly wall unit to prevent decay due to moisture generated inside the assembly wall unit by an external environment; and
a control unit for controlling information processing signals of the vibration processing module and the moisture removal module;
further comprising,
The vibration processing module,
a measuring unit for detecting vibrations and frequencies generated in the self-adjusting seismic wall;
a body surrounding the measuring part and including the measuring part inside;
a display unit for displaying the magnitude of the vibration frequency measured by the measuring unit on an outer peripheral surface of the assembled wall unit;
a shaft fastened to and fixed to the body and adjustable in length to a predetermined height;
a base horizontally fastened to the shaft to support the body;
a fixing part including the shaft and the base;
a connecting member which is bound to and fixed to the base;
a housing which is fastened to the connecting member and provided so that the pad unit can be bound;
a seating groove provided on the inner surface of the housing to bind and fix the pad part locking protrusion; and
a pad portion fixed to the housing to prevent vibrations generated from the self-adjusting seismic wall;
including,
The measurement unit,
a vibrating body that senses vibration;
a flow pipe sealing the vibrating body; and
a vibration measuring unit for measuring vibration transmitted through the flow pipe;
including,
The body is
It has a cylindrical, cylindrical or rectangular shape,
Forming a cover formed in a flat surface on one side,
a network characterized by wireless communication connected to the control unit;
further comprising,
The base is
One side corresponds to the shape of the main body and is characterized in that it has a cylindrical, cylindrical or rectangular shape.
including,
A locking groove for binding the locking projection is formed on the inner circumferential surface of the seating groove,
The pad part,
A plurality of absorbent materials are inserted therein and include a pad fastened to and fixed to the seating groove formed in the housing,
The pad is
Formed in the shape of a semicircle or a square with rounded corners,
Including a feature in which a plurality of locking projections can be fastened to the locking groove formed in the seating groove of the housing at the upper portion,
The moisture removal module,
a humidity sensor installed inside the assembly wall unit to measure the humidity therein; and
a heater installed inside the assembly wall unit to generate warm wind under the control of the control unit;
including,
The humidity sensor is
a transfer plate installed on the upper surface of the humidity sensor to transmit information about the humidity measured by the humidity sensor; and
a line unit extending from the transmission plate and transmitting information about the humidity measured by the humidity sensor to the control unit;
including,
The heater is
a fan rotating to generate a warm wind under the control of the control unit toward the assembly wall unit;
including,
The control unit is
generating earthquake-resistance-related information using the magnitude of the vibration sensed by the measuring unit, and transmitting the information to an external server through the network; and
controlling the operation of the fan and the heater based on the humidity detection result measured by the humidity sensor;
Self-adjusting seismic wall including
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