KR100946740B1 - Apparatus for testing structural strength of middle and long span structures in a heating furnace - Google Patents

Abstract

PURPOSE: A loading apparatus for a heating furnace is provided to carry out a heating-coupled fire-resistance experiment by applying a uniform load to a beam or slab type sample. CONSTITUTION: A loading apparatus for a heating furnace comprises a main body(120), a frame(150), a pressing unit(210), and a slab type tool(300). The main body includes an inner wall(112) made of a fireproof material and an inner heating space(116) in which a beam type sample(Sa) or a slab type sample(Sb) is mounted and heated. The frame is able to move along the length of the main body with wheels rolling on a rail arranged on both sides of the main body. The pressing unit is installed on the upper part of the frame and comprises wheels to move in the traverse direction of the main body.

Description

Furnace Load Loading Device {APPARATUS FOR TESTING STRUCTURAL STRENGTH OF MIDDLE AND LONG SPAN STRUCTURES IN A HEATING FURNACE}

The present invention relates to a device for conducting a heating interlocking fire resistance performance test by applying a variety of loads to the medium-to-intermediate member installed in the furnace, in more detail, it is possible to implement a variety of load loading conditions, evenly distributed load loading of the test body It is possible to perform load-loading heating experiments of various methods to efficiently perform loading-interlocking heating experiments of large-scale structures such as building slabs and deck plates, or tunnel structures, bridge truss, and ship deck plates. It relates to a furnace loading device.

At present, due to industrial development, population concentration, and urbanization, high-rise and large-scale buildings have been in recent years. Accordingly, when a fire occurs, a large-scale fire is induced, resulting in a sudden increase in material damage and casualties.

In the event of a fire of such a building, the structural members are exposed to high heat and structurally vulnerable and fail to maintain their design strength according to the high heat. As a result, a building often collapses easily due to a decrease in strength of the structure in case of fire, resulting in enormous human and property damage.

As such, the structural members subject to high heat in case of fire in a building structure determine the limit of the use performance or structural destruction according to the support conditions, load conditions, and fire exposure surface, as well as the physical and thermal characteristics of the materials constituting the fire. It is important to design the fire resistance of the structure considering the effect of

In the related art, there has been a case where a partial strength test is performed by applying heat to a structural member having a short length. However, such a conventional experimental equipment is capable of performing thermal interlocking experiments on specimens such as simple short length beams, which are used for high-rise and large-space buildings, such as 4m, 6m, and 10m length mid-long beams. It was a performance limitation that fire resistance performance test could not be performed on the real items such as short column, slab, joint frame, deck plate bridge truss and ship deck plate.

The present invention is to solve the conventional problems as described above, the object is to implement a variety of load loading conditions during the heating through the heating furnace, it is possible to load loads of the test specimen, load loading heating of various methods It is possible to experiment with load-interlocking heating experiment efficiently for real-world large-scale members such as 4m, 6m, 10m length heavy beam, short main column, slab, joint frame, deck plate bridge truss, ship deck plate, etc. Provided is a heating load carrying device that can be implemented.

In order to achieve the above object, the heating furnace load-bearing apparatus of the present invention includes an inner wall of a refractory, and includes a burner to form a heating space therein, and the heating space is equipped with a test specimen or a slab type test specimen. A body to be heated; A frame movable in the longitudinal direction of the main body with wheels movable on rails disposed on both sides of the main body; A pressing unit having a wheel mounted on an upper side of the frame and movable in a lateral direction of the main body, and having an actuator for applying a load on a test object; And a prosthetic jig and a slab jig mounted on an actuator of the pressing unit to apply a load to a prosthetic specimen or a slab type specimen, wherein the actuator is moved in the longitudinal and transverse directions of the main body to the prosthetic specimen or the slab type specimen. The test is carried out by applying a uniformly distributed load and conducting heat-linked fire resistance performance test. Therefore, the present invention is capable of equally distributed load loading of the test specimens, and load loading heating experiments of various methods can be performed, and thus loading and linking heating experiments of large structures such as building slabs and deck plates or tunnel structures can be performed.

And the present invention is preferably the prosthetic jig is fixed to the rod of the prosthetic actuator, the first beam pressing rod extending in the longitudinal direction of the main body, and a plurality of first rotatably mounted on both ends of the first beam pressing rod The first nut members of the upper end are screwedly connected to the first screw member, respectively, and are rotatably mounted on both ends of the plurality of second beam pressing rods extending in the longitudinal direction of the main body, and the respective second beam pressing rods. A plurality of beam pressing plates each of which is coupled with a plurality of second nut members at upper ends by screwing, between the rod of the beam actuator and the first beam pressing table, between the first beam pressing table and each first A hinge is mounted and rotatably connected between the two beam pressing members and between the second beam pressing member and each of the beam pressing plates.

In addition, the present invention is preferably the prosthesis test piece both ends are supported by the upright beam pedestal, respectively, the lower three sides are exposed to the inside of the main body of the heating furnace, the heating of the prosthetic jig in the longitudinal direction on the upper surface of the test specimen. Multiple beam press plates are arranged and subjected to an evenly distributed load through the beam actuator.

And the present invention is preferably a plurality of slab jig is fixed to the rod of the slab-type actuator, a plurality of first slab pressing rod extending in the longitudinal direction of the body and rotatably mounted on both ends of the first slab pressing rod, respectively. The first nut members of the upper end are respectively screwed to the first screw member of the plurality of second slab presses extending in the transverse direction of the main body and rotatably at both ends of the respective second slab presses. The second nut members of the upper end are connected to the plurality of mounted second screw members, respectively, by screwing, and are respectively rotated at both ends of the plurality of third slab presses extending in the longitudinal direction of the main body, and the respective third slab presses. The third nut members of the upper end are respectively connected by screwing to the plurality of third screw members that are mounted so as to extend in the lateral direction of the main body. Fourth nut members of the upper end are respectively connected to the fourth slab presser and the plurality of fourth screw members rotatably mounted at both ends of the fourth slab presser, respectively, by screwing, and are movable in the transverse direction of the main body. It includes a plurality of slab platen.

In addition, the present invention preferably preferably between the rod of the slab-type actuator and the first slab press, between the first slab press and each of the second slab press, the second slab press and each third slab pressurized A hinge is mounted and rotatably connected between the bars, between the third slab presser and each fourth slab presser, and between the fourth slab presser and each slab presser.

And the present invention is preferably the slab-type test body is supported on a rectangular slab pedestal mounted on the upper surface of the furnace body, the lower surface is exposed to the inside of the body of the furnace furnace heating the upper surface of the slab specimens In the slab-type jig, a plurality of slab platens are arranged and subjected to an evenly distributed load through the slab-type actuator.

According to the furnace load-bearing apparatus according to the present invention, the prosthetic actuator and the slab actuator of the pressurization unit are movable in the longitudinal direction and the transverse direction of the main body with respect to the prosthesis specimen or the slab specimen mounted on the main body of the furnace, respectively. Equilibrium loads are applied to the prosthesis specimen or slab specimen through the and slab jig, and the heat-linked fire resistance performance test is performed.

Therefore, according to the present invention, it is possible to implement various load loading conditions during heating through the heating furnace, and even load distribution of the test body is possible, and load loading heating experiments of various methods are possible, so that the lengths of 4m, 6m, and 10m length are long. Excellent effects are obtained that can accurately and efficiently carry out load-interlocking heating experiments on large-scale physical members such as beams, short columns, slabs, joint frames, deck plates, bridge truss, and ship deck plates.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, the furnace load-loading device 100 according to the present invention has an inner wall 112 made of a refractory material, and includes a burner 114 and a heating furnace in which a heating space 116 is formed ( It is mounted so as to be movable in the longitudinal direction to the main body 120 of the 110, such a heating furnace 110 is a test specimen (Sa) or a slab-type specimen (Sb) in the heating space 116 in the main body 120 It is mounted and heated to the temperature pattern of the building fire curve (KS or ISO Fire) or tunnel fire curve (RWS / RABT / MHC FIRE) required for fire resistance test.

And the furnace load loading device 100 according to the present invention, as shown in Figures 2a and 2b, may be mounted in the furnace 110, respectively, a plurality of sets, for example four sets, each of the main body Frame 150 is movable on the rail 140 disposed on both sides of the 120, such a frame 150 is provided with a wheel 162 at the bottom of the vertical stand 160 of the main body 120 Each structure is movable in the longitudinal direction.

As shown in FIGS. 3, 4A, and 4B, the frame 150 is heated on a plurality of vertical legs 160 standing upright on each rail 140 and the upper ends of the vertical legs 160. Including a crosspiece 180 installed to cross the main body 120 of the furnace 110 in the transverse direction as a whole it is made of a "┏┓" shaped structure of the Gantry (Gantry type).

In addition, the lower end of the vertical stand 160 is provided with a driving motor 164 for rotating the wheel 162, and a lifting cylinder 166 for raising and lowering the wheel 162, the drive motor 164 Is mounted on the lower structure of the vertical stand 160 is connected to the wheel 162 through the sprocket 168 and the chain 170 is possible to reverse the rotation of the wheel 162 by the operation of the drive motor 164.

In addition, the lifting cylinder 166 is installed vertically, pneumatically or hydraulically actuated, the wheel 162 is connected to the rod 166a so as to be rotatable, respectively.

Accordingly, when the lifting cylinder 166 operates to lower the rod 166a, the wheel 162 connected to the rod 166a presses the rail 140 under the riser 160 and thus the riser 160, that is, the frame ( Lift the 150 to the upper side so that only the wheel 162 on the rail 140 is in contact. In this state, when the driving motor 164 is operated, the frames 150 are moved on the rails 140, respectively.

When the frame 150 is moved to the desired position on the rail 140 as described above, the driving motor 164 is stopped and the lifting cylinder 166 is operated to raise the rod 166a. The vertical stand 160, ie, the frame 150, descends such that the lower surface of the vertical stand 160 is in surface contact with the upper surface of the rail 140.

At the lower end of the vertical stand 160, a plurality of screw holes 176 are formed to couple the bolts 174 to the plurality of screw holes 172 formed along the rail 140.

Accordingly, the lower screw hole 176 of the vertical stand 160 and the screw hole 172 of the rail 140 coincide with each other while the lower surface of the vertical stand 160 is in surface contact with the rail 140. Fixing with bolt 174 coupling as shown in the fixed position of the frame 150.

In addition, the frame 150 of the heating load-bearing apparatus 100 according to the present invention is configured such that the crossbar 180 is capable of height adjustment with respect to the vertical bar 160, the crossbar 180 is shown in FIG. As described above, a plurality of rollers 182 are rotatably mounted at both ends thereof to protrude toward the riser 160 and move along the riser 160.

In addition, the uprights 160 are mounted with vertically moving cylinders 190, each upright, and the rod 192 of the upright cylinders 190 is connected to the lower end of the crosspiece 180. Therefore, when the height of the crosspiece 180 is adjusted, the lifting and lowering of the crossbar 180 is performed by the operation of the vertical moving cylinder 190 provided on the vertical stand 160, and the crossbar is made after the height of the crossbar 180 is adjusted. When the screw holes 194 formed at both ends of the 180 and the plurality of screw holes 196 formed in the longitudinal direction at the upper side of the vertical stand 160 are matched to each other by the bolt 198, the cross bars 180 are perpendicular to the cross bar 180. Stand 160 is fixed to be combined.

Of course, if it is necessary to adjust the height of the crosspiece 180 again in this state, the bolts 198 connecting the crossbar 180 and the vertical stand 160 are dismantled, and the height is adjusted by operating the vertical moving cylinder 190. Next, fixing with the bolt 198 can achieve the height adjustment.

In addition, the heating load device 100 according to the present invention is provided on the upper side of the frame 150 is provided with a pressing unit 210 is provided with an actuator movable in the transverse direction of the main body 120. As shown in FIG. 3, the pressing unit 210 includes three actuators, in which a prosthetic actuator 220 is positioned in the center, and slab actuators 240 are located at both left and right sides thereof. The prosthetic actuator 220 and the slab actuator 240 are respectively disposed between a pair of side-by-side rung 180, as shown in Figure 5b, the support 230 is a cross-section 180 on the top Placed across.

The prosthetic actuator 220 and the slab actuator 240 are composed of cylinders 222 and 242 using pneumatic or hydraulic pressure, respectively, and the rods 222a and 242a are installed downward, respectively, and the rod ( At the ends of 222a) and 242a, prosthetic jig 260 and slab jig 300 will be described.

The prosthetic actuator 220 and the slab actuator 240 of the pressing unit 210 are provided with wheels 224 that are movable on the upper portion of the crosspiece 180 on the upper side of the furnace body 120 in the transverse direction. It is configured to be mobile.

On the other hand, the pressing unit 210 shown in Figures 5a and 5b, for example, shows a prosthetic actuator 220, such a left and right movable configuration provided in the prosthetic actuator 220 is located on both the left and right sides The same applies to the slab-type actuator 240, and for the sake of simplicity, the prosthetic actuator 220 will be described by way of example, and the slab-type actuator 240 will be briefly given with the same reference numerals. Shall be.

As described above, the prosthetic actuator 220 includes a plurality of wheels 224 moving on the crosspiece 180 at an upper end thereof, and a lifting cylinder 226 for lifting up and down each of the wheels 224. In addition, a plurality of screw holes 236 are formed at a lower end of the upper support 230 of the prosthetic actuator 220 to couple the bolts 234 to the plurality of screw holes 232 formed along the crosspiece 180.

Therefore, when the prosthetic actuator 220 of the pressing unit 210 moves from side to side on the crosspiece 180, the wheel 224 is lowered by the operation of the lifting cylinder 226 to press the crossbar 180, accordingly. The upper support 230 of the prosthetic actuator 220 is raised to support only the wheel 224 to be movable on the crosspiece 180.

Therefore, when the prosthetic actuator 220 is pushed in such a state, the wheels 224 rotate along the upper surface of the crosspiece 180 to move in the transverse direction of the main body 120 of the heating furnace 110.

In addition, after moving in this manner, in order to fix the position by operating the lifting cylinder 226, each of the wheels 224 are raised, the screw holes 236 provided in the upper support 230 of the prosthetic actuator 220 It is attached in correspondence with the screw hole 232 of the crosspiece 180. In such a state, if the screw holes 232 and 236 are fixed by the bolt 234, the frame 150 may be fixed.

Therefore, the prosthetic actuator 220 and the slab actuator 240 of the pressing unit 210 may be positioned in the transverse direction of the furnace body 120.

In addition, the heating load-bearing apparatus 100 according to the present invention includes a jig mounted on the actuator of the pressing unit 210 to apply a load to the prosthetic test body Sa or the slab test body Sb.

The jig is fixed to the rod 222a of the prosthetic actuator 220 and the prosthetic jig 260 as shown in FIGS. 6A and 6B to apply a uniformly distributed load to the prosthetic specimen Sa and the slab actuator 240. And a slab jig 300 as shown in FIGS. 7A and 7B, which are fixed to the rod 242a and apply an equal distribution load to the slab type test body Sb.

The prosthetic jig 260 has a first beam presser 262 made of a linear steel member having a central upper portion fixed to the rod 222a of the prosthetic actuator 220 and extending in the longitudinal direction of the main body 120. do. In addition, a plurality of first screw members 264a and 264b may be horizontally rotatable at both ends of the first beam pressing member 262 so as to be rotatable, respectively, such first screw members 264a and 264b. Both ends of the) are rotatably coupled by the bearing (B), one end (K) is protruded to both sides of the first beam pressing table 262, so that the worker through a separate hand tool (not shown) One screw member 264a and 264b can be rotated.

The first nut members 268a and 268b are connected to the plurality of first screw members 264a and 264b of the first beam pressing member 262 by screwing, respectively, and the length of the main body 120 is different. A plurality of second beam pressing bar (270a) (270b) extending in the direction is connected.

Therefore, when the operator rotates the first screw member 264a and 264b through a separate hand tool (not shown), the second beam pressing members 270a and 270b are respectively first nut members 268a and 268b. These can be linearly moved on each of the first screw members 264a and 264b to move the position in the longitudinal direction of the first beam pressing member 262, that is, in the longitudinal direction of the furnace body 120.

In addition, the prosthetic jig 260 rotates the bearings B such that the plurality of second screw members 272a and 272b are rotatable at both ends of the respective second beam pressing members 270a and 270b. It is mounted through, and similar to the first screw member (264a) 264b, one side end (K) protrudes to both sides of the second beam pressing table (270a) (270b) so that workers through a separate hand tool (not shown) The second screw members 272a and 272b can be rotated.

The second nut members 274a and 274b are respectively connected to the plurality of second screw members 272a and 272b of the second beam pressing members 270a and 270b by screwing, and the lower side thereof. Beam pressing plate 280 is connected to each. Therefore, the prosthetic jig 260 has a second nut member 274a and 274b linearly moving on each second screw member 272a and 272b when the operator rotates the second screw member 272a and 272b. The position of the beam pressing plate 280 in the longitudinal direction of the second beam pressing table (270a) (270b), that is, the longitudinal direction of the heating body main body 120 is possible.

The prosthetic jig 260 is between the rod 222a of the prosthetic actuator 220 and the first beam pressing table 262, and the first beam pressing table 262 and the second beam pressing table 270a. Hinge (H) is mounted and rotatably connected between the (270b) and the second beam pressing table (270a) (270b) and each of the beam pressing plate 280, such a hinge (H) coupling structure Rotation is generated at the end of the test object during the pressurization operation of the prosthetic actuator 220 through the protection of the prosthetic actuator 220 by preventing the occurrence of moment when bending or buckling occurs.

And the slab-type jig 300 provided in the heating load device 100 according to the present invention is fixed to the rod 242a of the slab-type actuator 240, as shown in Figure 7a and 7b, the main body And a first slab presser 302 extending in the longitudinal direction of 120.

A plurality of first screw members 304a and 304b are rotatably mounted on both ends of the first slab presser 302 so as to be rotatable, respectively, such first screw members 304a and 304b. Each end of the field is rotatably coupled by a bearing (B), one end (K) is protruded to both sides of the first slab presser 302 so that the operator first through a separate hand tool (not shown) The screw members 304a and 304b can be rotated.

The first nut members 308a and 308b are respectively connected to the plurality of first screw members 304a and 304b of the first slab presser 302 by screwing, and the length of the main body 120 is The plurality of second slab pressing rods 310a and 310b extending in the direction are connected to each other. Therefore, the second slab presser 310a (310b), respectively, when the operator rotates the first screw member (304a, 304b) through a separate hand tool (not shown), the first nut member (308a) (308b) They can be linearly moved on each of the first screw members 304a and 304b to positionally move in the longitudinal direction of the furnace body 120.

In addition, the slab-type jig 300 is a bearing (B) such that a plurality of second screw members 312a, 312b are rotatable so as to be rotatable at both ends of each of the second slab presser 310a, 310b. And the one end K is protruded to both sides of the second slab presser 310a and 310b, similarly to the first screw members 304a and 304b, so that workers can separate a hand tool (not shown). Through the second screw member (312a) (312b) is to be rotated.

The second nut members 314a and 314b are respectively connected to the plurality of second screw members 312a and 312b of the second slab presser 310a and 310b by screwing, respectively. A plurality of third slab pressing bars 316a and 316b extending laterally of the main body 120 are mounted.

In addition, a plurality of third screw members 318a and 318b rotatably mounted at both ends of each of the third slab pressers 316a and 316b may include upper third nut members 320a and 320b. These screws are connected to each other by a plurality of fourth slab pressing rods (322a, 322b) extending in the longitudinal direction of the body 120 is mounted.

The fourth nut members 326a and 326b at the upper end of the plurality of fourth screw members 324a and 324b rotatably mounted at both ends of each of the fourth slab pressers 322a and 322b, respectively. Each of the plurality of slab pressure plates 330 that are connected by screwing and movable in the direction of the main body 120 are connected to each other.

In this structure, the third screw members 318a and 318b and the fourth screw members 324a and 324b are the same as the first screw members 304a and 304b and the second screw members 312a and 312b. Rotation is possible by an operator, and the third slab presser 316a, 316b and the fourth slab presser 322a, 322b may be moved in the longitudinal direction and the transverse direction of the main body 120, respectively.

Therefore, such a slab jig 300, when the operator rotates the first screw member 304a (304b) and the third screw member (318a) (318b), the slab pressing plate in the longitudinal direction of the furnace body 120 ( 330 may be moved, and rotation of the second screw members 312a and 312b and the fourth screw members 324a and 324b causes the position of the slab pressure plates 330 to be transverse to the furnace body 120. You can move it.

And the slab jig 300 is between the rod 242a of the slab-type actuator 240 and the first slab presser 302, the first slab presser 302 and each of the second slab presser ( Between the third slab presser 316a and 316b between the second slab presser 310a and 310b and between the third slab presser 316a and 316b between 310a and 310b. A hinge H is mounted and rotatably connected between each fourth slab presser 322a and 322b and between the fourth slab presser 322a and 322b and each slab presser plate 330. As such, when the slab-type actuator 240 is pressurized through the hinge (H) coupling structure, rotation occurs at the end of the test object, and thus, when bending or buckling occurs, the moment is prevented from generating the slab-type actuator. Protect 240.

The process of applying a uniformly distributed load to the test specimen Sa or the slab type specimen Sb by using the furnace load-bearing apparatus 100 according to the present invention configured as described above, and conducting the heat-linked fire resistance performance test will be described. Let's do it.

First, the prosthesis Sa is mounted to the heating furnace 110, as shown in FIGS. 8A and 8B, and the prosthesis Sa is mounted on an upright beam pedestal 350 as shown in FIG. Supported, as shown in Figure 8b, the lower three surfaces are exposed to the inside of the main body 120 of the heating furnace 110 in the state where the heating is made prosthetic jig 260 in the longitudinal direction on the upper surface of the prosthetic test object (Sa). A plurality of beam pressing plate 280 of the is arranged, and is subjected to an equal distribution load through the beam actuator 220.

That is, the prosthetic jig 260 moves in the longitudinal direction of the prosthetic specimen Sa through the rotation of the first and second screw members 264a and 264b and the second screw members 272a and 272b. Since the position can be adjusted, various fire resistance performance experiments are possible for prostheses (Sa) of various lengths and sizes.

In addition, the slab type test body (Sb) is mounted to the heating furnace 110, as shown in Figure 9a and 9b, this slab type test body (Sb) is a rectangular slab pedestal 360 as shown in Figure 1 It is mounted on the upper surface of the heating body main body 120, and then supported on the rectangular slab pedestal 360, the lower surface is exposed to the inside of the body 120 of the heating furnace 110, the heating is made In the slab-type specimen (Sb) in the plurality of slab pressing plate 330 of the slab-type jig 300 is disposed, is subjected to an equal distribution load through the slab-type actuator 240.

In this case, the slab-type jig 300 has the length of the slab-type specimen Sb through the slab pressure plate 330 through the rotation of the first screw member (304a) (304b) and the third screw member (318a) (318b). It is possible to adjust the position by moving in the direction, the position adjustment is moved by moving in the width direction of the slab type test body (Sb) through the rotation of the second screw member (312a) (312b) and the fourth screw member (324a) (324b). Because of this, various fire resistance performance experiments are possible for slab-type specimens (Sb) of various sizes.

Therefore, the present invention is thus capable of equally distributed load loading of the test specimen (Sa) and the slab type specimen (Sb), and the load-loading heating experiments of various methods are possible, such as building slabs, deck plates, or tunnel structures. Loading and interlocking heating experiment of the structure can be effectively performed.

 As described above, according to the present invention, the prosthetic actuator 220 and the slab actuator 240 of the pressing unit 210 with respect to the prosthetic test body Sa or the slab test body Sb mounted on the main body 120 of the heating furnace 110. ) Are movable in the longitudinal and transverse directions of the main body 120, and is equally distributed to the prosthetic specimen Sa or the slab specimen Sb through the prosthetic jig 260 and the slab jig 300, respectively. The fire-interlocking fire resistance test is carried out.

Therefore, the present invention can implement a variety of load loading conditions during the heating through the heating furnace 110, it is possible to load the load evenly distributed test specimens, load loading heating experiments of various methods is possible 4m, 6m, 10m length It is possible to perform loading and interlocking heating experiments accurately and efficiently on real-world large-scale members such as mid to long beams, short cylinders, slabs, joint frames, deck plates, bridge truss, and ship deck plates.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

1 is an exploded perspective view showing the entire structure of a heating furnace to which a heating load device according to the present invention is applied.

Figure 2a is a plan view showing the overall structure of the heating load device and the heating furnace according to the present invention.

Figure 2b is a side view showing the overall structure of the heating load device and the heating furnace according to the present invention.

Figure 3 is a front view showing a heating load device in accordance with the present invention.

Figure 4a is a front view showing a frame moving structure provided in the heating load device according to the present invention.

Figure 4b is a side view showing the longitudinal movement structure of the main body of the frame provided in the heating load device according to the present invention.

Figure 5a is a front view showing a transverse movement structure of the actuator provided in the heating load device according to the present invention.

Figure 5b is a side cross-sectional view showing a transverse movement structure of the actuator provided in the heating load device according to the present invention.

Figure 6a is a side view showing the prosthetic jig provided in the heating load device according to the present invention.

Figure 6b is a front view showing the prosthetic jig provided in the heating load device according to the present invention.

Figure 7a is a side view showing a slab-type jig provided in the heating load device according to the present invention.

Figure 7b is a front view showing a slab-type jig provided in the heating load device according to the present invention.

Figure 8a is a side view for carrying out the heat interlocking fire resistance performance test on the prosthesis specimen using the furnace load loading device according to the present invention.

8B is a front view for conducting a heat interlocking fire resistance test on a prosthesis specimen by using a heating load carrying device according to the present invention.

Figure 9a is a side view for conducting a thermal interlocking fire performance test on the slab-type test body using a heating load carrying device according to the present invention.

Figure 9b is a front view for conducting a heating interlocking fire performance test on the slab-type test body using a heating load device according to the present invention.

Description of the Related Art

100 ..... Furnace Loading Devices 112 ..... Inner Wall

114 ..... Burner 116 ..... Heating Space

120 ..... Body 140 ..... Rail

150 ..... Frame 160 ..... Vertical Stand

162 ..... wheels 164 ..... drive motor

166 ..... lift cylinder 166a ..... loaded

168 ..... Sprocket 170 ..... Chain

172,176 ..... screw holes 174 ..... bolts

180 ..... crossbar 182 ..... roller

190 ..... Load Cylinder 192 .....

194,196 ..... Screw holes 198 ..... Bolt

210 ..... Pressurization 220 ..... Prosthetic actuator

222,242 .... Cylinders 222a, 242a ..... Rod

224 ...... wheel 226 ..... lifting cylinder

230 ...... top support 232,236 ..... screw holes

234 ..... Bolt 240 ..... Slab type actuator

260 ..... Prosthetic jig 262 ..... 1st beam presser

264a, 264b .... First screw member 268a, 268b ..... First nut member

270a, 270b ..... 2nd beam presser 272a, 272b ..... 2nd screw member

274a, 274b ..... second nut member 280 ..... pressure plate

300 ..... slab type jig 302 ..... 1st slab press

304a, 304b ..... First screw member 308a, 308b ..... First nut member

310a, 310b ..... 2nd slab presser 312a, 312b ..... 2nd screw member

314a, 314b ..... 2nd nut member 316a, 316b ..... 3rd slab press

318a, 318b ..... Third screw member 320a, 320b .... Third nut member

322a, 322b ..... Fourth slab presser 324a, 324b .... Fourth screw member

326a, 326b ..... Fourth nut member 330 ..... slab pressure plate

B ..... Bearing K ...... One end

H ..... hinge Sa ...... prosthesis

Sb ..... slab type specimen

Claims (6)

An inner wall 112 is formed of a refractory, and a burner 114 is provided to form a heating space 116 therein. The heating space 116 is equipped with a test specimen Sa or a slab type specimen Sb. A body 120 to be heated; A frame 150 having a wheel 162 movable on rails 140 disposed on both sides of the main body 120 and movable in a longitudinal direction of the main body 120; A wheel 224 mounted on an upper side of the frame 150 and movable in a lateral direction of the main body 120 is provided, and actuators 220 and 240 are provided to apply a load on a test object Sa (Sb). Pressed portion 210; And And a prosthetic jig 260 mounted on the actuators 220 and 240 of the pressing unit 210 to apply a load to the prosthetic test body Sa or the slab test body Sb, and the slab jig 300. The actuators 220 and 240 are moved in the longitudinal direction and the transverse direction of the main body 120 to apply an equal distribution load to the prosthetic test body Sa or the slab test body Sb, and perform the heat-linked fire resistance performance test. Furnace load loading device, characterized in that. According to claim 1, The prosthetic jig 260 is fixed to the rod 222a of the prosthetic actuator 220, the first beam pressing rod 262 extending in the longitudinal direction of the main body 120 and the first The first nut members 268a and 268b at the upper end are screwed to the plurality of first screw members 264a and 264b rotatably mounted at both ends of the beam presser 262, respectively, A plurality of second beam pressing rods 270a and 270b extending in the longitudinal direction of 120 and rotatably mounted on both ends of the respective second beam pressing rods 270a and 270b, respectively. The second nut members 274a and 274b at the top of the two screw members 272a and 272b include a plurality of beam pressing plates 280 connected by screwing, respectively, and the rod 222a of the prosthetic actuator 220. And between the first beam pressing table 262, between the first beam pressing table 262 and each of the second beam pressing tables 270a and 270b and the second beam pressing table 270a and 270b. With each Heater loading device, characterized in that the hinge (H) is mounted between the holding plate (280) is rotatably connected. According to claim 1, The prosthetic test object (Sa) is supported at both ends of the upright beam pedestal 350, the lower three sides are exposed to the inside of the main body 120 of the heating furnace 110, the heating is performed Furnace loading device, characterized in that a plurality of beam pressing plate 280 of the prosthetic jig 260 in the longitudinal direction on the upper surface of the prosthetic test (Sa), is subjected to a uniform distribution load through the prosthetic actuator (220). According to claim 1, The slab jig 300 is fixed to the rod 242a of the slab-type actuator 240, the first slab presser 302 extending in the longitudinal direction of the main body 120, and the First nut members 308a and 308b of the upper end are connected to the plurality of first screw members 304a and 304b rotatably mounted at both ends of the first slab presser 302 by screwing, A plurality of second slab presser 310a, 310b extending in the longitudinal direction of the main body 120 and a plurality of rotatably mounted at both ends of each of the second slab presser 310a, 310b, respectively. The second nut members 314a and 314b of the upper end are connected to the second screw members 312a and 312b by screwing, respectively, and the plurality of third slab pressers 316a extending in the transverse direction of the main body 120. 316b and a plurality of third screw members 318a (3) rotatably mounted at both ends of each of the third slab pressers 316a and 316b, respectively. 18b) and a plurality of fourth slab pressers 322a and 322b extending in the longitudinal direction of the main body 120 by screwing the upper third nut members 320a and 320b, respectively, Fourth nut members 326a and 326b of the upper end are screwed into a plurality of fourth screw members 324a and 324b rotatably mounted at both ends of the fourth slab presser 322a and 322b, respectively. Heating device loading apparatus characterized in that it comprises a plurality of slab pressing plate 330 connected to move in the transverse direction of the main body (120). The method of claim 4, wherein between the rod 242a of the slab-type actuator 240 and the first slab presser 302, the first slab presser 302 and each second slab presser 310a Between the second slab presser 310a and 310b and each of the third slab presser 316a and 316b between 310b and the third slab presser 316a and 316b. A hinge H is mounted and rotatably connected between the fourth slab presser 322a and 322b and between the fourth slab presser 322a and 322b and the respective slab presser plates 330. Furnace loading equipment. According to claim 1, The slab-type test object (Sb) is supported on a rectangular slab pedestal 360 mounted on the upper surface of the furnace body 120, the lower surface is the body 120 of the furnace 110 A plurality of slab pressure plates 330 of the slab jig 300 is disposed on the upper surface of the slab type test body Sb in a state of being exposed to the inside and heated, and is subjected to an equal distribution load through the slab type actuator 240. Furnace load loading device, characterized in that.

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