KR102193492B1 - Overpressure outlet with rotation control structure - Google Patents

Abstract

The present invention relates to an overpressure outlet having a rotation control structure, and more specifically, to an overpressure outlet that consists of a frame body formed in a through frame structure, and a blocking unit installed in the frame body to open or close the frame body. The frame body is further provided with a control unit to control the rotation of the blocking unit. Moreover, a fusible link is separated by heat generated by operating a heater by a signal from a sensor such as a smoke detector or a flame detector, and a weight panel acting as a stopper moves to prevent an opening and closing unit from opening while rotating, thereby preventing the spread of a fire through the overpressure outlet.

Description

Overpressure outlet with rotation control structure

The present invention relates to an overpressure outlet having a rotation control structure, and more particularly, a fusible link is separated by heat generated by operating a heating heater by a signal from a detection sensor such as a smoke detector or a flame detector, and performs a stopper role. It relates to an overpressure outlet having a rotation control structure capable of preventing a fire from spreading through the overpressure outlet by blocking the weight panel from moving and opening while the opening and closing portion is rotated.

In general, when a fire occurs in a building, a signal is detected by a fire detector, and when this signal is received, a water spray fire extinguishing facility such as a sprinkler installed along the ceiling sprays fine and uniform water at a constant pressure into particles such as fog. The fire is extinguished by covering the combustion surface in the protected space.

However, since water spray fire extinguishing equipment cannot be used for dangerous substances that are difficult to extinguish with water or objects requiring electrical insulation due to high-pressure electric equipment, fire extinguishing equipment is used to extinguish fires by releasing extinguishing agents under the pressure of pressurized gas. Are doing.

However, since the fire extinguishing facility must release the fire extinguishing agent at high pressure due to the nature of the fire extinguishing agent, in the event of a fire, the internal structure of the building may be damaged due to an instantaneous excessive increase in pressure in the enclosed space of the protected area. An overpressure outlet is installed on the wall to discharge the pressure to the outside.

However, the conventional overpressure outlet requires a locking function of the overpressure outlet because the fire can spread through the open overpressure outlet when the fire extinguishing gas is not released into the building or the fire is not extinguished. Since the fusible link mounted on the unit is separated by heat from the fire, it takes a considerable amount of time to close the overpressure outlet, so that a fire may spread before the fire zone is formed.

The above-described invention refers to the background technology in the technical field to which the present invention belongs, and does not mean the prior art.

Registered Patent No. 10-1487899

The present invention was conceived to solve the above-described conventional problems, and an object of the present invention is to separate the fusible link by heat generated by operating the heating heater by a signal from a detection sensor such as a smoke detector or a flame detector, An object of the present invention is to provide an overpressure outlet having a rotation control structure capable of preventing a fire from spreading through the overpressure outlet by blocking the weight panel serving as a stopper from moving and opening while the opening and closing portion is rotated.

The present invention consists of a frame body formed in a through frame structure, and a blocking portion installed in the frame body to open or close the frame body, and a control unit is further provided in the frame body to control the rotation of the blocking portion. It is characterized by that.

In addition, the blocking portion is made of a rotation shaft formed in the frame body, an opening and closing portion that is axially coupled to the rotation shaft, the opening and closing portion is a rotation panel condensed to be rotated to the rotation shaft, and an upper end portion is fixed to the rotation panel, It is composed of an opening and closing panel that rotates together with the rotating panel portion, and the opening and closing panel is characterized in that the weight panel is axially coupled to rotate on one surface.

In addition, the frame body is installed with the rotation shaft at a predetermined interval, the opening and closing portion is installed to be rotated on the rotation shaft, and the opening and closing portion installed on the rotation shaft is connected by the weight panel.

In addition, the control unit includes a control shaft formed in the blocking portion, a control housing formed in the frame body and having an outlet at a bottom, a heating heater formed in the control housing and driven by receiving a signal from a detection sensor, A fusible link connected to and fixed to the heating heater to receive heat generated from the heating heater, and a weight member connected to and fixed to the fusible link.

In addition, locking panels are further formed on both sides of the weight member, and locking shafts are formed on the control housing to engage the locking panels, so as to prevent the weight member from being separated from the control housing.

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The overpressure discharge port having the rotation control structure of the present invention is separated by the heat generated by the heat generated by the operation of the heating heater by a signal from a detection sensor such as a smoke detector or a flame detector, and the weight panel serving as a stop moves to move the opening and closing part. By blocking the opening while rotating, there is an effect that it is possible to prevent the fire from spreading through the overpressure outlet.

1 is a cross-sectional view showing an overpressure outlet having a rotation control structure according to the present invention.
2 to 4 are cross-sectional views showing an operating state of an overpressure outlet having a rotation control structure according to the present invention.
5 is a partially enlarged cross-sectional view showing an overpressure outlet having a rotation control structure according to the present invention.
6 is a partially enlarged cross-sectional view showing an operating state of an overpressure outlet having a rotation control structure according to the present invention.
7 is a front view showing a cross-section of a control unit installed in an overpressure outlet having a rotation control structure according to the present invention.
8 is a front view showing the operating state of the control unit installed in the overpressure outlet having a rotation control structure according to the present invention.
9 is a cross-sectional view showing another embodiment of an overpressure outlet having a rotation control structure according to the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of an overpressure outlet having a rotation control structure according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

In addition, the following examples are not intended to limit the scope of the present invention, but are presented merely as examples, and there may be various embodiments implemented through the present technical idea.

1 is a cross-sectional view showing an overpressure outlet having a rotation control structure according to the present invention. 2 to 4 are cross-sectional views showing an operating state of an overpressure outlet having a rotation control structure according to the present invention. 5 is a partially enlarged cross-sectional view showing an overpressure outlet having a rotation control structure according to the present invention. 6 is a partially enlarged cross-sectional view showing an operating state of an overpressure outlet having a rotation control structure according to the present invention. 7 is a front view showing a cross-section of a control unit installed in an overpressure outlet having a rotation control structure according to the present invention. 8 is a front view showing the operating state of the control unit installed in the overpressure outlet having a rotation control structure according to the present invention. 9 is a cross-sectional view showing another embodiment of an overpressure outlet having a rotation control structure according to the present invention.

As shown in the drawing, the overpressure outlet 10 (hereinafter referred to as an overpressure outlet for convenience of description) having a rotation control structure according to the present invention increases the pressure inside the building when the fire extinguishing agent is sprayed, resulting in damage to the building. The overpressure outlet 10 is designed to prevent the overpressure, thus the overpressure outlet 10 is composed of a frame body 20 and a blocking portion 30.

The frame body 20 is fitted and fixed to the wall of the corresponding protection zone formed in the building.

The frame is made of a through frame structure, and the material is made of a metal material or a synthetic resin material.

The frame is made of a rectangular frame or a rectangular tube structure, and it is also possible to form a circular or polygonal shape.

The blocking part 30 is installed on the frame body 20 to open or close the frame body 20.

The blocking part 30 is a rotation shaft 31 inserted into the inner side of the side panels of the frame body 20, and an opening/closing part that is axially coupled to the rotation shaft 31 to open or close the frame body 20 (32), wherein the opening/closing part 32 is condensed to be rotated on the rotation shaft 31 and a panel structure rotating panel 321 having a hollow structure formed with a rotating hole, and an upper end portion at the lower end of the rotating panel 321 The rivet is fastened and fixed, and consists of an opening/closing panel 322 rotated together with the rotating panel 321 part.

The opening/closing panel 322 is shaft-coupled so that the weight panel 322a is rotated on one surface, so that when a fire occurs and the fire extinguishing agent is sprayed, the pressure inside the building increases, and the opening/closing part 32 moves the rotation shaft 31 The opening and closing part rotated by the weight of the weight panel 322a when the pressure inside the building is lowered by opening the frame body 20 while rotating to the center for ventilation. As 32) returns, the frame body 20 is closed.

At this time, the rotation shaft 31 is installed at a certain interval on the frame body 20, the opening/closing part 32 is installed to be rotated on the rotation shaft 31, and the opening/closing part installed on the rotation shafts 31 32 is connected by the weight panel 322a. The open panel is axially coupled by connecting the opening and closing panels 322 of the opening and closing portion 32.

At this time, the frame body 20 is further provided with a control unit 40 to control the rotation of the blocking portion 30.

The control unit 40 includes a control shaft 41 whose one end is bolted to the rotation panel 321 of the blocking part 30, and a rivet fastened to the upper portion of the frame body 20 and fixed to the bottom surface. The control housing 42 is formed with 421 and an accommodation space is formed therein, and a heating heater which is a heating wire or a heat panel that is bolted to and fixed to the control housing 42 and driven by receiving a signal from the detection sensor 100 ( 43), a fusing link 44 that is screwed to the heat generating heater 43 to receive heat generated from the heat generating heater 43, and a metal material that is screwed and fixed to the fusing link 44 It consists of a weight member 45 formed of.

The fusible link 44 includes a fixing panel made of a metal material bolted to the heating heater 43 and a moving panel bolted to and fixed to the weight member 45, and the fixing panel and the moving panel It is connected by mutual soldering, and the moving panel is separated from the fixed panel as the solder is melted by the heat transmitted from the heating heater 43, and the control housing together with the weight member 45 by its own weight ( 42), the lower end of the weight member 45 is disposed in contact with the end of the control shaft 41 to support the control shaft 41, so that the opening/closing part 32 It acts as a stopper to prevent rotation.

The detection sensor 100 electrically connects the heating heater 43 and the relay, and when it detects smoke or flame due to a fire, it transmits the signal to the heating heater 43 or extinguishes it at the receiving panel of the corresponding protection area. When sending a signal to the drug starting device, the signal is transmitted to the heating heater 43 at the same time.

At this time, after a certain period of time (10 seconds release, 60 seconds release, 120 seconds release depending on the characteristics of the fire extinguishing agent), the pressure inside the building decreases and the weight member 45 The opening/closing part 32 is restored by its own weight, and the heating heater 43, which has received a signal from the detection sensor 100 or the reception panel of the corresponding protection area, is heated and said within 120 seconds after the discharge of each extinguishing agent ends. The weight of the control shaft 41 of the opening/closing part 32 returned by dissolving the overpressure by the weight member 45 moved downward while melting the solder of the fuzzy link 44 to separate the fuzzy link 44 By preventing the member 45 from being caught and rotated, the fire is prevented from spreading by the flow of air due to the opening of the opening and closing part 32 again.

At this time, the heating heater 43 is bolted to a fastener having a through structure formed on the front panel of the control housing 42 to be fixed.

At this time, the weight member 45 is further integrally formed with locking panels 451 on both sides, and the control housing 42 is integrally formed with a locking shaft 422 so that the locking panels 451 are locked on the inner surface. Or bolted and fixed, so that the weight member 45 moves downward on the drawing, the lower end is drawn out to the outside, and then is caught by the locking shaft 422, thereby preventing separation from the control housing 42. do.

The control shaft 41 prevents breaking when the weight member 45 drawn out from the control housing 42 is pressed, and when the opening/closing part 32 of the blocking part 30 rotates, the weight member 45 An elastic shock absorbing means 50 is further provided to buffer the shock transmitted to the.

The elastic shock absorbing means 50 includes a fastening groove 51 formed at the end of the control shaft 41, an elastic buffering coil spring 52 fitted into the fastening groove 51, and the elasticity One end is inserted into the coupling groove 51 to be supported by the buffer coil spring 52, and the pressure shaft 53 is welded to and fixed to the elastic buffer coil spring 52, and the other end of the pressure shaft 53 A pressure panel 54 that is attached or screwed to be fixed, an elastic buffer panel 55 made of a synthetic resin material having elasticity that is attached to and fixed to one surface of the pressure panel 54, and the elastic buffer panel 55 It is formed integrally on one side and is made of a synthetic resin material having elasticity that presses the weight member 45 by the rotation of the opening and closing part 32, and a curved elastic pressing protrusion 56 formed in a hemispherical dome structure. Consisting of, in the process of the control shaft 41 pressing the weight member 45 when the opening and closing part 32 rotates, the pressing shaft 53, the elastic cushioning panel 55, and the elastic pressing protrusion 56 ) By the elasticity of the shock transmitted to the control shaft 41 can be buffered, the weight member 45 and the control shaft 41 are prevented from being damaged, and the elastic pressing protrusion 56 It is easy to replace when worn or damaged by friction.

Here, roller grooves are formed on the weight member 45 on a surface abutting the inner surface of the control housing 42, and a guide roller is rotated so that a part of the roller groove is exposed to the outside, and the weight member ( It is preferable to prevent the weight member 45 from rubbing or being caught with the control housing 42 while the 45) moves downward by its own weight in the control housing 42.

One embodiment of the present invention described above is merely exemplary, and those of ordinary skill in the technical field to which the present invention belongs will appreciate that various modifications and other equivalent embodiments are possible. . Therefore, it will be appreciated that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

10: overpressure outlet
20: frame body
30: blocking part
31: rotating shaft
32: opening and closing part
321: rotating panel
322: opening and closing panel
322a: weight panel
40: control unit
41: control axis
42: control housing
421: outlet
422: locking shaft
43: heating heater
44: Fusible Link
45: weight member
451: locking panel
50: elastic shock absorbing means
51: binding groove
52: elastic buffer coil spring
53: pressure shaft
54: pressure panel
55: elastic cushioning panel
56: elastic pressing protrusion
100: detection sensor

Claims (6)

Frame body formed in a through frame structure; And
It is installed in the frame body, consisting of a blocking portion for opening or closing the frame body,
The frame body is further provided with a control unit to control the rotation of the blocking portion,
The control unit includes a control shaft formed in the blocking portion,
A control housing formed on the frame body and having an outlet on a bottom surface thereof,
A heating heater formed in the control housing and driven by receiving a signal from a detection sensor,
A fusible link connected to and fixed to the heating heater and receiving heat generated from the heating heater;
Overpressure outlet having a rotation control structure, characterized in that consisting of a weight member connected to and fixed to the fusible link.
The method of claim 1,
The blocking portion and a rotation shaft formed in the frame body,
It consists of an opening and closing part that is axially coupled to be rotated to the rotation shaft,
The opening/closing part includes a rotating panel condensed to be rotated on the rotating shaft,
An upper end portion is fixed to the rotating panel and configured as an opening/closing panel rotated with the rotating panel,
The overpressure outlet having a rotation control structure, characterized in that the weight panel is axially coupled to rotate on one side of the opening and closing panel.
The method of claim 2,
The frame body has a rotation control structure, characterized in that the rotation shaft is installed at a certain interval, the opening and closing part is installed to rotate on the rotation shaft, and the opening and closing part installed on the rotation shaft is connected by the weight panel Overpressure outlet.
delete The method of claim 3,
The weight member is further formed with locking panels on both sides,
The overpressure discharge port having a rotation control structure, characterized in that a locking shaft is formed in the control housing to engage the locking panel, so as to prevent the weight member from being separated from the control housing.
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