KR102069440B1 - seismic retrofitting structure of refrigeration warehouse - Google Patents

Abstract

The present invention relates to a new structure of a seismic reinforcement structure for a refrigeration warehouse to reduce the vibration applied to the refrigeration warehouse during an earthquake, thereby improving the seismic performance of the refrigeration warehouse. According to the present invention, the seismic reinforcement structure for a refrigeration warehouse, when the vibration of the refrigeration warehouse is detected by a vibration sensor (60), a control means (80) controls a rotation driving motor (21) to rotate a turntable (20) so that a rotation unit (30) faces the direction in which the refrigeration warehouse vibrates and then drives a position adjusting means (33) and a rotation driving means (40) of the rotation unit (30) to rotate the rotation unit (30). The present invention can attenuate the vibration of the refrigeration warehouse and can prevent secondary damage caused by the fall of products inside the refrigeration warehouse.

Description

Seismic retrofitting structure of refrigeration warehouse}

The present invention relates to a seismic reinforcement structure for a refrigerated warehouse having a new structure to attenuate the vibration of the frozen warehouse during an earthquake so as to prevent the second damage from falling or falling inside the freezer.

Recently, as earthquakes occur frequently, earthquake-resistant design has been made to withstand earthquakes when building a freezer warehouse.

However, when an earthquake occurs, the entire freezer warehouse is swayed laterally, so that not only the direct damage of the freezer warehouse is damaged, but also the shelf, desk, or bookcase inside the freezer warehouse collapses or hangs on the ceiling. The backs crashed, causing secondary damage to people indoors.

However, the general earthquake resistance design for the freezer is not only to prevent damage to the freezer by the earthquake by reinforcing the strength of the freezer, it is difficult to prevent the freezing warehouse itself to shake sideways to cause secondary damage. .

Therefore, there is a need for a new method to solve this problem.

10-1253519,

The present invention is to solve the above problems, the inside of the freezer for a new structure to attenuate the vibration of the freezer warehouse when the earthquake occurs to prevent the secondary damage from falling or falling inside the freezer warehouse. The purpose is to provide a progressive steel structure.

The present invention for achieving the above object is fixed to the freezing warehouse 10, and is coupled to the upper surface of the fixing stand 10 is rotatably coupled by the rotation drive motor 21 and the upper surface A turntable 20 having a rotation bracket 23, a rotation unit 30 rotatably coupled to the rotation bracket 23 in a forward and backward direction, and a rotation unit 30 connected to the rotation unit 30. Rotating driving means 40 for rotating in the front and rear direction, the vibration sensing sensor 60 is provided in the fixed base 10 to measure the vibration frequency and amplitude and the vibration direction of the freezer warehouse by the earthquake, and the vibration detection Receiving a signal from the sensor 60 includes a control means 80 for controlling the operation of the rotary drive motor 21, the rotation unit 30 and the rotation drive means 40, the rotation unit 30 is A rotation bar 31 rotatably coupled to the rotation bracket 23 in a forward and backward direction, and The weight 32 is slidably coupled to the rotation bar 31 in the longitudinal direction of the rotation bar 31, and the weight 32 is connected to the weight 32 so that the weight 32 is in the longitudinal direction of the rotation bar 31. Position adjusting means 33 to be adjusted to the position and the rotation bar 31 is provided with a position detecting means 34 for detecting the position of the weight 32, the control means 80 When the vibration of the freezer warehouse is detected by the vibration sensor 60, after controlling the rotation drive motor 21 to rotate the turntable 20 so that the rotation unit 30 is in the direction in which the freezer warehouse vibrates, Refrigerant warehouse for earthquake resistance, characterized in that for reducing the vibration of the freezer by rotating the rotation unit 30 by driving the position adjusting means 33 and the rotation driving means 40 of the rotation unit 30. Steel structure is provided.

According to another feature of the invention, the position adjusting means 33 is arranged to be parallel to the rotating bar 31 on one side of the rotating bar 31 and the middle portion is screwed to penetrate the weight 32 Including a lead screw 33a and a drive motor 33b connected to the lead screw 33a to forward and reverse rotate the lead screw 33a, the lead screw 33a is rotated forward and backward with the drive motor 33b. By the screw action of the lead screw (33a) is provided a seismic reinforcement structure for the freezer, characterized in that the weight 32 is slide in the longitudinal direction of the rotation bar 31 to adjust the position.

According to another feature of the invention, the fixing means 50 is provided on the upper surface of the fixing table 10 further comprises a fixing means 50, the fixing means 50 of the turntable 20 On the fixing block 51 and the fixing block 51 is provided on the upper surface of the fixing table 10 to be able to move forward and backward to the circumference and the fixing groove 51a in which the circumference of the turntable 20 is inserted and fixed. Is connected and includes a forward and backward drive unit 52 for forward and backward moving the fixed block 51, the control means 80 is the vibration sensor 60 when the vibration of the freezer warehouse is detected the rotary drive motor 21 After controlling the rotation of the turntable 20, the fixing means 50 is operated to move the fixing block 51 to the circumference of the turntable 20 so that the circumference of the turntable 20 is fixed block 51. Is inserted into the fixing groove (51a) of the to be fixed so as not to move My advanced steel structure for cold storage is provided.

According to another feature of the invention, the turntable 20 further comprises an auxiliary vibration detecting sensor 70 for detecting the vibration generated in the turntable 20, the control means 80 is the fixing means After fixing the turntable 20 by using the 50, the rotation driving means 40 is driven to rotate the rotation unit 30, and at the same time, the vibration detecting sensor 60 and the auxiliary vibration detecting sensor 70. Receiving a signal of, when the vibration value measured by the vibration sensor 60 and the auxiliary vibration sensor 70 differs by more than the reference, to stop the operation of the rotation drive means 40 An earthquake-resistant reinforcement structure is provided.

According to the seismic reinforcement structure for a freezer warehouse according to the present invention, when the vibration detection of the freezer warehouse vibration is detected by the vibration sensor 60, the control means 80 controls the rotary drive motor 21 to rotate the rotation unit ( 30 rotates the turntable 20 to face the direction in which the freezing warehouse vibrates, and then drives the position adjusting means 33 and the rotating driving means 40 of the rotating unit 30 to rotate the rotating unit 30. By rotating, the vibration of the freezer is attenuated, and there is an advantage of preventing the secondary damage from falling or falling of the inside of the freezer.

1 is a side cross-sectional view showing a seismic reinforcement structure for a refrigerated warehouse according to the present invention,
Figure 2 is a plan view showing a seismic reinforcement structure for a freezer warehouse according to the present invention,
3 is a circuit diagram of a seismic reinforcing structure for a refrigerated warehouse according to the present invention,
4 to 7 is a reference diagram showing the action of the seismic reinforcement structure for a refrigerated warehouse according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 to 7 illustrate a seismic reinforcement structure for a refrigerated warehouse according to the present invention, the seismic reinforcement structure for a refrigerated warehouse is fixed to the freezer storage 10, and the side surface on the upper surface of the fixing stand (10) Rotation unit is rotatably coupled to the rotary drive motor 21 and the turntable 20 is provided with a rotation bracket 23 on the upper surface, and the rotation unit rotatably coupled to the rotation bracket 23 in the front-rear direction ( 30) and a rotation driving means 40 connected to the rotation unit 30 to rotate the rotation unit 30 in the front and rear directions, and provided on an upper surface of the fixing table 10 to fix the turntable 20. Fixing means (50), provided on the holder 10, vibration detection sensor 60 for measuring the vibration frequency and amplitude and the vibration direction of the freezer warehouse due to the earthquake, and the turntable 20 is provided in the turntable ( Auxiliary vibration sensor (7) for detecting the vibration generated in the 20 0) and the control means 80 connected to the vibration sensor 60 and the auxiliary vibration sensor (70).

The fixing stand 10 is formed of a metal panel with high strength, and a leg member 11 extending downward is provided on the circumferential surface thereof, and the leg member 11 is anchored by the roof of the freezer warehouse. It is fixed to the upper surface of the panel (1).

In addition, a circular protrusion 12 protruding upward is formed at the center of the upper surface of the holder 10.

The turntable 20 is formed in a disk shape of a high strength metal material, and is rotatably coupled to the protrusion 12 of the holder 10 through a bearing 22 provided on the lower side.

The pivot bracket 23 is provided at the center of the upper surface of the turntable 20.

The rotary drive motor 21 is fixed to the lower side of the fixed base 10, the upper rotation axis 21a is connected to the lower side of the turntable 20 is the forward and reverse rotation of the turntable 20 in accordance with the drive It is configured to.

The pivoting unit 30 is pivotally coupled to the pivoting bracket 23 in a forward and backward direction, and pivotally coupled to the pivoting bar 31 in a longitudinal direction of the pivoting bar 31. The weight 32 and the position adjusting means 33 is connected to the weight 32 to adjust the position of the weight 32 in the longitudinal direction of the rotation bar 31, and the rotation bar 31 Is provided is composed of a position detecting means 34 for detecting the position of the weight 32.

The weight 32 is configured in the form of a block formed so that the through-hole 32a through which the pivoting bar 31 is slidably coupled penetrates the upper and lower surfaces in the central portion.

The position adjusting means 33 is arranged to be parallel to the rotating bar 31 on one side of the rotating bar 31, the middle portion of the lead screw (33a) screwed to pass through the weight 32, and It is composed of a drive motor 33b connected to the lead screw 33a to reversely rotate the lead screw 33a. When the lead screw 33a is reversely rotated with the drive motor 33b, the screw of the lead screw 33a is rotated. By the action, as shown in FIG. 7, the weight 32 slides in the longitudinal direction of the pivoting bar 31 and is positioned.

The position detecting means 34 is to use a linear scale fixed to one side of the rotation bar 31, one side is coupled to the inner peripheral surface of the through hole 32a of the weight 32, the weight 32 When the position is moved in the longitudinal direction of the rotation bar 31, the weight 32 to measure the distance traveled to function to output to the control means (80).

As such, the linear scale used to detect the position of the weight 32 has been developed and used in various kinds, and further detailed description thereof will be omitted.

The rotation driving means 40 uses a hydraulic cylinder which is connected at both ends to the turntable 20 and the rotation bar 31 so that the rotation bar 31 rotates according to expansion and contraction.

At this time, the rotation drive means 40 is the base end is hinged to the support 25 provided on the upper surface of the turntable 20, the piston rod 41 extending forward is hinged to the rotation bar 31 When the rotating means 40 is expanded and contracted, as shown in Fig. 6, the rotating bar 31 is rotated in the front-rear direction.

The fixing means 50 is provided on the upper surface of the fixing table 10 so as to be able to move forward and backward to the circumference of the turntable 20, and the fixing groove 51a in which the circumference of the turntable 20 is inserted and fixed at the front surface thereof is fixed. Block 51 and the fixed block 51 is connected to the forward and backward drive unit 52 for advancing the fixed block 51 forward and backward.

To this end, a plurality of guide rails 24 extending to the center of the turntable 20 is provided on the upper surface of the fixing table 10, the fixing block 51 is slidably coupled to the guide rails 24. do.

The front and rear vibration driving unit 52 is connected to the fixed block 51 uses an air cylinder for forward and backward forward and backward driving unit 52 according to the expansion and contraction.

The vibration sensor 60 is to use the acceleration sensor provided on one side of the holder 10, when the earthquake occurs and the freezer warehouse vibrates, and thus the holder 10 vibrates laterally, The frequency and amplitude of the vibration of the stator 10 and the direction in which the stator 10 vibrates are measured and output to the control means 80.

The auxiliary vibration sensor 70 uses an acceleration sensor provided on one side of the upper surface of the turntable 20, and is generated in the turntable 20 when the rotation unit 30 is rotated by the rotation means 40. The vibration is measured and output to the control means (80).

Since the acceleration sensor used as the vibration sensor 60 and the auxiliary vibration sensor 70 is developed and used in various kinds, the detailed description thereof will be omitted.

The control means 80 receives the signal of the vibration sensor 60, when the freezer is detected to be vibrated by the earthquake, the rotary drive motor 21, the rotation unit 30 and the rotation drive means 40 And by controlling the operation of the fixing means 50 to rotate the rotation unit 30 in the vibration direction of the freezer, to reduce the vibration of the freezer.

In detail, as shown in FIG. 1, the control means 80 retracts the fixing block 51 of the fixing means 50 so that the turntable 20 can be rotated.

In addition, when an earthquake is generated and the stator 10 is vibrated by the vibration detecting sensor 60, the control means 80 receives a signal output from the vibration detecting sensor 60, and the rotation drive. As shown in FIG. 4 by driving the motor 21, the turntable 20 is rotated so that the rotation unit 30 faces the vibration direction of the holder 10.

That is, when the holder 10 is vibrated in the direction shown by the arrow of the dotted line in Figure 4, the control means 80 controls the operation of the rotation drive motor 21, the rotation unit 30 is The turntable 20 is rotated so that the rotating direction is parallel to the direction in which the holder 10 vibrates.

Then, when the rotation of the turntable 20 is completed, the control means 80, as shown in Figure 5, by operating the forward and backward drive unit 52 of the fixing means 50 to the fixed block 51 By advancing toward the circumference of the turntable 20, the fixing groove 51a of the fixing block 51 is coupled to the circumference of the turntable 20, so that the turntable 20 is fixed.

In addition, the control means 80 drives the rotation driving means 40 according to the frequency of the freezer warehouse measured by the vibration detecting sensor 60, as shown in FIG. ) Is rotated in the direction in which the holder 10 is vibrated, so that the vibration of the freezer is attenuated.

That is, when the pivot unit 10 is rotated by the rotation unit 30 using the rotation drive means 40, a force is applied in a direction opposite to the direction in which the fixture 10 is vibrated in response thereto. The vibration of the freezer can be reduced.

In addition, the control means 80 controls the operation of the position adjusting means 33 while receiving a signal from the position detecting means 34 in accordance with the amplitude of the freezer warehouse measured by the vibration detecting sensor 60. As shown in FIG. 7, the weight 32 is generated when the pivot unit 30 is rotated by adjusting the position of the weight 32 and the proximal end of the pivoting bar 31, that is, in the up and down direction. Adjust the repulsive force.

That is, in the state where the rotation unit 30 is rotated in the front and rear direction at the same speed, when the weight 32 moves to the proximal end of the rotation bar 31, the repulsive force generated when the rotation unit 30 is rotated is When the weight 32 is transferred to the tip of the rotation bar 31, the repulsive force generated when the rotation unit 30 is rotated is increased.

Therefore, when the freezer is large in amplitude, the weight 32 is moved to the tip of the pivot bar 31, and when the freezer is small, the weight 32 is moved to the proximal end of the pivot bar 31. By moving, the refrigeration warehouse can attenuate vibrations to an accurate degree by applying an appropriate level of repulsion to the refrigeration warehouse.

In addition, the control means 80 receives the signals of the vibration detection sensor 60 and the auxiliary vibration detection sensor 70 when driving the rotation drive means 40 to rotate the rotation unit 30, When the vibration value measured by the vibration sensor 60 and the auxiliary vibration sensor 70 is different than the reference, the operation of the rotation drive means 40 is stopped.

That is, the turntable 20 is rotatably coupled to the fixture 10 through the bearing 22, so that when the repulsive force generated by the rotation unit 30 is applied to the turntable 20, the bearing 22 The damaged means or the turntable 20 may flow laterally, so that the control means 80 rotates the turntable 20 and then fixes the turntable 20 using the fixing means 50. As a result, the rotational unit 30 is prevented from being damaged by the repulsive force generated by the rotation of the turntable 20 and the fixing table 10.

In the state in which the turntable 20 is normally fixed by the fixing means 50, the vibration values measured by the vibration sensor 60 and the auxiliary vibration sensor 70 have a similar shape.

By the way, when the turntable 20 is not normally fixed due to a failure in the fixing means 50 or for various other reasons, flow may be generated in the turntable 20 when the rotation unit 30 is rotated.

In this way, when the rotation unit 30 is continuously rotated in the state in which the turntable 20 flows, the connection portion between the turntable 20 and the fixing table 10 is damaged, and in the severe case, the turntable 20 is fixed. Separate from (10) to damage the freezer.

On the other hand, when the turntable 20 is not accurately fixed to the holder 10 and flows as described above, the vibration values measured by the vibration sensor 60 and the auxiliary vibration sensor 70 have different forms. .

Therefore, the control means 80 is said to be the flow of the turntable 20 when the vibration value measured by the vibration sensor 60 and the auxiliary vibration sensor 70 differs by more than a predetermined reference. By judging, by stopping the rotation of the rotation unit 30, it is possible to prevent the connection between the turntable 20 and the fixture 10, or to separate the turntable 20 from the fixture 10.

When the vibration sensor 60 no longer detects the vibration, the control means 80 determines that the earthquake is over and stops the rotation of the rotation unit 30.

According to the seismic reinforcement structure for a freezer warehouse configured as described above, when vibration of the freezer warehouse is sensed by the vibration sensor 60, the control unit 80 controls the rotary drive motor 21 to rotate the rotation unit 30. ) Rotates the turntable 20 to face the direction in which the freezing warehouse vibrates, and then drives the position adjusting means 33 and the rotating driving means 40 of the rotating unit 30 to rotate the rotating unit 30. By rotating, the vibration of the freezer is attenuated, and there is an advantage that the secondary damage can be prevented from falling or falling inside the freezer.

And, the position adjusting means 33 is arranged to be parallel to the rotating bar 31 on one side of the rotating bar 31 and the middle portion of the lead screw 33a screwed to pass through the weight 32 And a drive motor 33b connected to the lead screw 33a to forward and reverse rotate the lead screw 33a. When the lead screw 33a is rotated forward and backward with the drive motor 33b, the lead screw 33a is rotated. By the screw action of the weight 32 is slid in the longitudinal direction of the rotation bar 31, the position is adjusted, there is an advantage that can effectively adjust the position of the weight (32).

In addition, a fixing means 50 for fixing the turntable 20 is provided on an upper surface of the fixing stand 10, and the fixing means 50 is capable of advancing back and forth to the circumference of the turntable 20. The fixed block 51 is provided on the upper surface and the front surface of the turntable 20 is formed with a fixing groove 51a for inserting and fixing the circumferential portion of the turntable 20, and is connected to the fixing block 51 to advance the fixed block 51 back and forth. It is composed of a front and rear vibration driving unit 52, the control means 80 to rotate the turntable 20 by controlling the rotary drive motor 21 when the vibration of the freezing warehouse is detected by the vibration detection sensor (60). After the operation, the fixing means 50 is operated to move the fixing block 51 to the circumference of the turntable 20 so that the circumference of the turntable 20 is inserted into the fixing groove 51a of the fixing block 51 to move. By being fixed so as not to be, the rotation unit 30 is rotated in the front and rear direction foot When the reaction force to be exerted on the turn table 20, there is an advantage that can prevent damage to the connections of the turntable 20 and the fixing means (50).

In addition, the turntable 20 is provided with an auxiliary vibration detection sensor 70 for detecting the vibration generated in the turntable 20, the control means 80 is the turntable 20 by using the fixing means (50) After fixing the, driving the rotation drive means 40 to rotate the rotation unit 30, and at the same time receives a signal of the vibration sensor 60 and the auxiliary vibration sensor 70, the vibration sensor When the vibration value measured by the 60 and the auxiliary vibration sensor 70 differs by more than a reference, by stopping the operation of the rotation drive means 40, the turntable 20 and the fixed table 10 There is an advantage that can effectively prevent the connection is damaged.

10. Fixture 20. Turntable
30. Rotating unit 40. Rotating drive means
50. Fixing means 60. Vibration sensor
70. Auxiliary vibration sensor 80. Control means

Claims (4)

A fixed base 10 fixed to the freezer,
A turntable 20 rotatably coupled to an upper surface of the fixing table 10 and rotated by a rotation driving motor 21 and having a rotation bracket 23 on an upper surface thereof;
A rotation unit 30 rotatably coupled to the rotation bracket 23 in the front and rear directions;
A rotation driving means 40 connected to the rotation unit 30 to rotate the rotation unit 30 in the front and rear directions;
Vibration detection sensor (60) provided in the fixed base (10) for measuring the vibration frequency and amplitude and vibration direction of the freezer warehouse by the earthquake;
Receiving a signal of the vibration sensor 60 includes a control means for controlling the operation of the rotary drive motor 21, the rotation unit 30 and the rotation drive means 40,
The rotation unit 30
A rotation bar 31 rotatably coupled to the rotation bracket 23 in a forward and backward direction;
A weight weight 32 slidably coupled to the rotation bar 31 in the longitudinal direction of the rotation bar 31;
A position adjusting means 33 connected to the weight 32 to allow the weight 32 to be adjusted in the longitudinal direction of the rotation bar 31;
It is provided on the rotation bar 31 includes a position detecting means 34 for detecting the position of the weight 32,
The control means 80 controls the rotary drive motor 21 when the vibration sensor 60 detects the vibration of the freezing warehouse, so that the rotation unit 30 faces the direction in which the freezing warehouse vibrates. 20, after rotating the rotation unit 30 and the rotation driving means 40 of the rotation unit 30 to rotate the rotation unit 30 to reduce the vibration of the freezer,
The position adjusting means 33
A lead screw 33a which is disposed to be in parallel with the pivoting bar 31 on one side of the pivoting bar 31 and screwed to penetrate the weight 32;
Including a drive motor (33b) connected to the lead screw (33a) for forward and reverse rotation of the lead screw (33a),
When the lead screw 33a is rotated forward and backward with the driving motor 33b, the weight 32 is slid in the longitudinal direction of the rotation bar 31 by the screw action of the lead screw 33a to adjust its position. A seismic reinforcement structure for a frozen warehouse, characterized in that.
delete The method of claim 1,
It is further provided with a fixing means 50 provided on the upper surface of the fixing table 10 for fixing the turntable 20,
The fixing means 50 is
A fixing block 51 provided on an upper surface of the holder 10 so as to be able to move back and forth to the circumference of the turntable 20, and a fixing block 51 having a fixing groove 51a in which a circumference of the turntable 20 is inserted and fixed at the front surface thereof;
It is connected to the fixed block 51 includes a forward and backward drive unit 52 for advancing forward and backward the fixed block 51,
The control means 80 controls the rotary drive motor 21 to rotate the turntable 20 when the vibration sensor 60 detects the vibration of the freezing warehouse, and then operates the fixing means 50. The fixing block 51 is advanced to the circumference of the turntable 20 so that the circumference of the turntable 20 is inserted into the fixing groove 51a of the fixing block 51 to be fixed so as not to move. Seismic reinforcement structure.
The method of claim 3, wherein
Further provided on the turntable 20 further includes an auxiliary vibration detecting sensor 70 for detecting the vibration generated in the turntable 20,
The control means 80 uses the fixing means 50 to fix the turntable 20, and then drives the rotation driving means 40 to rotate the rotation unit 30, and at the same time, the vibration sensor ( 60) and a signal of the auxiliary vibration sensor 70, when the vibration value measured by the vibration sensor 60 and the auxiliary vibration sensor 70 is different than the reference, the rotation drive means Earthquake-resistant reinforcement structure for the freezer, characterized in that to stop the operation of the (40).

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