KR100456485B1 - A transformation survey method and apparatus of the underground - Google Patents

Abstract

The present invention relates to a method for measuring underground deformation using an optical fiber sensor capable of directly measuring the deformation of the ground, and a device thereof, which includes a circular sensor rod provided with a straight optical fiber in a longitudinal direction with a pair of upper and lower pairs and a pair of both sides. Buried in the interior of the installation; Detecting and collecting a length variation of each optical fiber through a measuring instrument in real time by varying a wavelength of a light source irradiated from a measuring instrument to each optical fiber provided outside the circular sensor rod; Receives the length deformation data of each section of the optical fiber through the controller connected to the measuring instrument, and compares the length deformation of each section of the optical fiber forming a pair of up and down, and calculates the vertical deformation direction and deformation amount of the ground for each section, Comparing the length deformation of each section of the paired optical fiber mutually to calculate the horizontal deformation direction and the deformation amount of the ground for each section, the ground for each section based on the vertical, horizontal deformation direction and the deformation amount of each section Comprising the step of calculating the deformation direction and the amount of deformation.

Description

Ground deformation measurement method and apparatus using optical fiber sensor {A transformation survey method and apparatus of the underground}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for measuring underground deformation using an optical fiber sensor and an apparatus thereof, and to a method for measuring underground deformation using an optical fiber sensor that can directly measure changes in the ground.

In general, the change in the ground is caused by natural causes such as fine earthquake and heavy rain or by artificial causes such as various civil works.

However, if the change of the ground occurs due to the above reasons, due to the subsidence of the ground, various pipes buried in the ground and various structures built on the ground may collapse or slope surface may collapse, An accident such as this collapse occurs.

Thus, in order to prevent such collapse, in recent years, equipment for predicting the collapse of the slope is known and in use, but the development of equipment that can predict the collapse of the flat surface collapse and tunnels, etc. is insufficient.

And as the equipment applied to the collapse of the slope, equipment that is predicted collapse of the slope as the length of the wire by interconnecting the pile and the wire to the ground through the wire is known.

However, when measuring the slope using such equipment, it is possible to predict the surface collapse of the slope, but it is impossible to measure the soil inside the slope, so that the slope of the slope cannot be predicted.

Accordingly, the present invention has been invented to solve the above problems, it is an object of the present invention to provide a method for measuring the earth deformation using the optical fiber sensor that can measure the underground changes such as slope and the flat surface and the tunnel around the tunnel and its device It is done.

In addition, the circular sensor rod for measuring the change in the ground by dividing the section by measuring the ground deformation by section, there is also the purpose to quickly grasp the signs of collapse.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing an earthquake deformation measuring apparatus according to a first embodiment of the present invention.

2 is a process chart showing a measurement method through the earth deformation measurement apparatus of the first embodiment according to the present invention.

3 is a view showing the installation state of the deformation measurement instrument of the first embodiment according to the present invention,

Figure 3a is a longitudinal cross-sectional state of the ground,

3B is an enlarged cross-sectional view taken along the line A-A of FIG. 3A.

Figure 4 is a block diagram showing the earthquake deformation measurement apparatus of a second embodiment according to the present invention.

5 is a process chart showing a measurement method through the earth deformation measurement apparatus of the second embodiment according to the present invention.

6 is a view showing the installation state of the deformation measurement instrument of the second embodiment according to the present invention,

6A is a longitudinal section of the ground;

FIG. 6B is an enlarged sectional view taken along the line B-B in FIG. 6A.

7 is an enlarged schematic view of a modification of each section of the second embodiment according to the present invention;

8 is a schematic cross-sectional view showing a state in which the measuring device of the second embodiment according to the present invention is applied to tunnel construction.

9 is an enlarged view of a portion C of FIG. 8;

<Description of the symbols for the main parts of the drawings>

1: circular sensor rod

2: optical fiber

3: Instrument

31: light source generator

32: data collector

4: Controller

The present invention for achieving the above object comprises the steps of: buried in the inside of a circular sensor rod provided with a straight optical fiber in the longitudinal direction in the upper, lower pair and both pairs on the outside; Detecting and collecting a length variation of each optical fiber through a measuring instrument in real time by varying a wavelength of a light source irradiated from a measuring instrument to each optical fiber provided outside the circular sensor rod; Receives the length deformation data of each section of the optical fiber through the controller connected to the measuring instrument, and compares the length deformation of each section of the optical fiber forming a pair of up and down, and calculates the vertical deformation direction and deformation amount of the ground for each section, Comparing the length deformation of each section of the paired optical fiber mutually to calculate the horizontal deformation direction and the deformation amount of the ground for each section, the ground for each section based on the vertical, horizontal deformation direction and the deformation amount of each section Calculating the deformation direction and the deformation amount of the;

In addition, a buried sensor rod is installed buried in the ground or inside the structure and provided with a straight optical fiber in a pair of upper and lower pairs and both sides; A light source generator for measuring the length strain of each optical fiber by varying the wavelength of the light source to each optical fiber of the circular sensor rod, and measuring the length strain for each section in real time while irradiating different wavelength light sources. An instrument comprising a data collector for collecting data; The length deformation data of each section of the optical fibers collected by the measuring instrument are input, and the length deformation of each section of the up and down pair of optical fibers is compared with each other to calculate the vertical deformation direction and the deformation amount of the ground for each section. Comparing the length deformation of each section of a pair of optical fibers to calculate the horizontal deformation direction and the deformation amount of each section for each section, and based on the vertical and horizontal deformation amount of each section, the deformation direction and deformation amount of each section of the ground Controller for calculating the; characterized in that the earth deformation measuring device consisting of.

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

1 is a view illustrating a deformation deformation measurement apparatus according to a first embodiment according to the present invention, wherein the measurement deformation measurement device according to the first embodiment according to the present invention is buried in the ground, and the upper and lower pairs and the pair of both sides are straight optical fibers. A circular sensor rod (1) provided with a longitudinal direction (2), a light source generator (31) for irradiating a light source to each optical fiber (2) of the circular sensor rod (1), and four optical fibers (2) while irradiating a light source A measuring instrument 3 including a data collector 32 for collecting data while measuring in real time the length strain of each optical fiber 2 through the deformation of a light source of the optical fiber 2), and the optical fibers 2 collected from the measuring instrument 3. It is composed of a controller (4) for receiving the length deformation data to calculate the change in the ground.

That is, the controller 4 receives the length deformation data of the optical fiber 2 collected from the measuring instrument 3, and compares the length deformation of the optical fiber 2 constituting the upper and lower pairs with each other based on this. Calculates the vertical deformation direction and the deformation amount of the fiber, and compares the length deformations of the paired optical fibers 2 with each other to calculate the horizontal deformation direction and the deformation amount of the ground, and the deformation direction and deformation amount of the ground based on the vertical and horizontal deformation amounts. It can be calculated.

In addition, the optical fiber 2 on the outside of the circular sensor rod 1 is firmly fixed through fixing means such as an adhesive material, and is configured to be deformed together with the deformation of the circular sensor rod 1.

Therefore, FIG. 2 is a process chart showing a measurement method using the earth deformation measurement apparatus of the first embodiment according to the present invention, and the earth deformation measurement method using the earth deformation measurement apparatus of the first embodiment according to the present invention will be described as follows. .

First, a step 100 is installed to bury the circular sensor rod 1 provided with the optical fiber 2 in the longitudinal direction in a pair of up and down pairs and both sides on the outside.

Next, measuring the length deformation of each optical fiber 2 through the light source deformation of the four optical fibers (2) while irradiating a light source to each optical fiber (2) of the circular sensor rod (1) installed in the underground through the measuring instrument (3) Proceed to step 101 of collecting and detecting in real time through (3). That is, the irradiation of the light source is made through the light source generator 31 included in the measuring device 3, and the data of measuring the length deformation of the optical fiber 2 is transmitted to the data collector 32 included in the measuring device 3 in real time. To be collected.

Next, the length deformation data of each optical fiber 2 is input through the controller 4 connected to the measuring instrument 3, and the vertical deformation of the inside of the underground is compared by comparing the length deformation of the optical fibers 2 constituting the upper and lower pairs with each other. Calculates a direction and a deformation amount, and calculates a horizontal deformation direction and a deformation amount in the underground by comparing the length deformations of the paired optical fibers 2 with each other, and based on the vertical and horizontal deformation directions and the deformation amount, By carrying out the step 102 of calculating the amount of deformation, the change in the ground can be measured.

That is, in the deformation direction and the deformation amount calculation step of the ground, the vertical deformation amount of the ground can be calculated by the difference in the change length of each of the optical fibers 2 forming a pair of up and down, each of the optical fibers forming a pair of both Based on the difference in the change lengths in (2), the horizontal deformation direction and deformation amount of the ground can be calculated. Therefore, when the vertical and horizontal deformation directions and deformation amount are converted into displacement vectors, the deformation direction and the change amount of the ground can be calculated.

In other words, if the difference minus the changed length of the lower optical fiber 2 is changed from the changed length of the upper optical fiber 2, it can be seen that the change of the ground occurs in the downward direction. It can be seen that it rises in the upward direction. Similarly, it can be seen that when the difference minus the changed length of the other optical fiber 2 minus the changed length of the one optical fiber 2 is a change in the ground occurs in one direction, on the contrary, when the difference is- It can be seen that occurs in the other direction.

Referring to this in more detail with reference to the accompanying drawings, Figure 3 shows a state of installation of the deformation measurement instrument of the first embodiment according to the present invention, Figure 3a is a longitudinal cross-sectional state of the ground, Figure 3b is AA of Figure 3a Line enlarged cross-sectional view is shown.

3A and 3B, in the case where the middle of the circular sensor rod 1 embedded in the ground is settled toward one side and the lower portion of the ground, the circular sensor rod 1 is provided at the upper portion. As the length of the upper optical fiber 2 is stretched and the length of the lower optical fiber 2 is extended, it can be seen that the vertical load is generated downward, and the lower portion is changed through the length difference between the upper and lower optical fibers 2. It is possible to grasp the amount of change in the underground.

In addition, as the length of one optical fiber 2 provided on one side of the circular sensor rod 1 is extended and the length of the optical fiber 2 is stretched on the other side, it can be understood that a horizontal load is generated on one side. Through the length difference of (2), it is possible to grasp the amount of change in the ground which changes to one side.

Therefore, if the vertical and horizontal deformation directions and deformation amount are converted into displacement vectors, the deformation direction and the change amount of the ground can be calculated in three dimensions.

Therefore, the measurement apparatus and method of the first embodiment can measure the ground deformation of the slope and the flat surface to prevent collapse accidents, as well as predict the collapse of the membrane during construction of the tunnel.

4 is a diagram illustrating the earth deformation measurement device according to the second embodiment of the present invention, wherein the earth deformation measurement device according to the second embodiment of the present invention is buried in the ground and has a pair of upper and lower pairs and a pair of both sides of the straight optical fiber. A circular sensor rod (1) equipped with an optical fiber grating sensor and a wavelength of a light source are varied in each optical fiber 2 of the circular sensor rod 1 to change the length of each optical fiber 2 by a section of a predetermined length. A measuring device 3 including a light collecting device 33 for measuring data and a data collecting device 32 for collecting data while measuring the length deformation in real time for each section while irradiating light sources having different wavelengths; It is composed of a controller (4) for receiving the length deformation data of the optical fiber (2) collected from 3) to calculate the change in the ground.

The light source generator 33 is already known. That is, the light source generator 33 for irradiating the light source while changing the wavelength of the light source is already known and in use. If the wavelength of the light source is changed in this way, each optical fiber ( In 2), the reflection section of the light source can be partitioned according to the wavelength type of the light source. In other words, a light source having a unique wavelength can pass only one section of the optical fiber. If the wavelength is varied, the optical fiber 2 can be divided into several sections. It is possible to measure the change in length of each section divided by the measuring instrument (3).

In addition, the controller 4 receives the length-deformation data for each section of the optical fiber 2 collected by the measuring instrument 3, and mutually crosses the length-deformation of each section of the optical fiber 2 forming the upper and lower pairs. Comparing to calculate the vertical strain of the ground for each section, and to compare the length strain of each section of the optical fiber (2) forming a pair of both sides to calculate the horizontal strain of the ground for each section, the vertical, horizontal for each section Based on the deformation amount, the deformation direction and deformation amount of the ground for each section can be calculated.

In addition, the optical fiber 2 on the outside of the circular sensor rod (1) is firmly fixed through a fixing means such as adhesive, it is configured to be deformed together with the deformation of the circular sensor rod (1).

Accordingly, FIG. 5 is a flowchart illustrating a measurement method using the earth deformation measurement apparatus according to the second embodiment of the present invention, and the earth deformation measurement method using the earth deformation measurement apparatus according to the first embodiment of the present invention is as follows. .

First, the step 200 is carried out to bury the circular sensor rod (1) having the optical fiber 2 in the longitudinal direction in a pair of up, down and both pairs on the outside.

Next, by varying the wavelength of the light source irradiated from the measuring device 3 to each optical fiber 2 provided on the outside of the circular sensor rod 1, the length deformation of each optical fiber 2 for each section of a predetermined length measuring instrument 3 In step 201 of detecting and collecting in real time. That is, the irradiation of light sources having different wavelengths is made through the light source generator 31 included in the measuring device 3, and the data measuring the length deformation of each section in the optical fiber 2 is included in the measuring device 3. The data collector 32 is to be collected in real time.

Then, the length deformation data of each optical fiber 2 is received through the controller 4 connected to the measuring device 3, and the length deformation of each section of the optical fiber 2 forming the upper and lower pairs is compared with each other for each section. Calculate the vertical strain of the ground, calculate the horizontal strain of the ground for each section by comparing the length strain of each section of the two pairs of optical fibers (2), and based on the vertical and horizontal strain of each section By performing the step of calculating the deformation direction and the deformation amount of the ground for each section, the change of the ground can be measured.

That is, in the step of calculating the deformation direction and the deformation amount of the ground, the vertical deformation direction and the deformation amount of each section with respect to the ground change can be calculated by the difference of the change length of each section of the optical fiber 2 constituting the upper and lower pairs. The horizontal deformation direction and the deformation amount of each section with respect to the underground change can be calculated by the difference in the change lengths of the optical fibers 2 constituting the pair of both sides. Accordingly, when the vertical and horizontal deformation directions and deformation amounts for each section are converted into displacement vectors, the deformation directions and changes in each section of the ground can be calculated in three dimensions.

In other words, if the difference of the subtracted length of the lower optical fiber 2 of the same section from the changed length of any one section in the upper optical fiber 2 is +, it can be seen that the ground change of the section occurs downward. On the contrary, if the difference is-, it can be seen that the change of the ground occurs in the upward direction. Similarly, when the difference in the one-side optical fiber 2 minus the changed length of the other optical fiber 2 in the same section is +, it can be seen that the change in the ground occurs in one direction, and vice versa. If the difference is-, the change in the ground occurs in the other direction.

More specifically, FIG. 6 is a view illustrating an installation state of the underground deformation measuring apparatus according to the second embodiment of the present invention. FIG. 6A is a longitudinal cross-sectional view of the ground, and FIG. 6B is an enlarged cross-sectional view taken along line B-B of FIG. 6A.

6A and 6B, when the circular sensor rod 1 embedded in the ground is deformed in various directions with respect to the change in the ground, the upper optical fiber provided at the upper portion of the circular sensor rod 1 is provided. As the length of each section of (2) is stretched or stretched and the length of the lower optical fiber 2 is also stretched or stretched, it can be understood that the vertical load is generated to the bottom or top of each section, and the upper and lower optical fibers of each section ( The difference in length of 2) can be used to grasp the change in the ground of each section. In addition, in the circular sensor rod 1, the length of each section of the optical fiber 2 is stretched or stretched, and the horizontal load is generated to one side or the other side as the length of each section of the optical fiber 2 is stretched or stretched on the other side. It can be grasped, and it is possible to grasp the amount of change in the ground of each section through the length difference of each section of the both optical fibers (2).

Therefore, if the vertical and horizontal deformation directions and deformation amounts obtained in each section of the optical fiber 2 are converted into displacement vectors, the deformation direction and change amount of the ground in each section can be calculated.

On the other hand, based on the deformation direction and the deformation amount of the ground for each section of the circular sensor rod (1) obtained in the step of calculating the deformation amount, the deformation direction and the deformation amount of the ground calculated for each section through the controller (4) By integrating from the end to the opposite end, the deflection of the opposite end and the deflection of each section can be calculated.

That is, the deflection of the circular sensor rod (1) located on the outside of the ground by setting the end of the circular sensor rod (1) to be the innermost in the state in which one end of the circular sensor rod (1) is inserted into the ground It can be calculated.

7 is an enlarged view of a variation of each section of the second embodiment according to the present invention, and calculates the deflection of each section or the deflection of the opposite side to the reference point in the circular sensor rod 1 with reference to FIG. The analogy of the equation is as follows.

First, in deriving the deflection calculation formula, if the sign is defined with reference to Figs. 4 to 7, L : the length of each initial section, h: the diameter of the circular sensor rod, ε: strain, ε _u : circular sensor rod (1) Strain length of the upper optical fiber 2 (or one of the two optical fibers 2) of the upper optical fiber 2, ε _L : of the lower optical fiber 2 of the circular sensor rod 1 (or both optical fibers 2) The other side optical fiber 2) strain length, R: radius of curvature, θ: angle of curvature arc, θ _i ; Any i-th deflection angle, θ _i-1 : i-1-th deflection angle (the deflection angle of any immediately preceding i-th section), V _i : any i-th deflection, V _i-1 : i-1 th Deflection is defined as deflection of any interval immediately before the i-th.

Therefore, when the ground is changed in the state in which the circular sensor rod 1 embedded in the ground is embedded in the ground, deformation of one section causes a curvature deformation. Therefore, the length of the arc formed by one section of the deformed circular sensor rod 1 corresponds to the value of the radius multiplied by the angle of the curvature arc.

so, Wow, Equation

Therefore, through the above equation, Is developed.

So in the above formula Assume that A is If you find the equation, and you find the radius of curvature R in this equation, Is developed.

And in the above formula Assume that B is Formula is established, and when the expressions are expanded, Is developed by using this expression Is developed.

Therefore, the second derivative of the deflection becomes 1 / curvature radius. Equation

And the first derivative of the deflection is the deflection angle. The same expression as When you define it as The expression of is developed.

Therefore, integrating the deflection angle causes deflection, and since deflection is cumulative, the i th deflection is obtained by using the i-1 th deflection and the i-1 th deflection angle to obtain an arbitrary deflection of the i section. Equation 1 can be obtained.

[Equation 1]

Therefore, the arbitrary i-th deflection through [Equation 1], the deflection of each section of the circular sensor rod (1), as well as the opposite end of the reference stage by substituting the i-1 th deflection and deflection angle into the above equation Sag can also be obtained.

In other words, while repeating the calculation process by substituting the deflection of each section from the reference stage to the opposite stage into the above equation, the deflection of the opposite end of the reference stage can be finally obtained.

Therefore, through the measurement apparatus and method of the second embodiment, it is possible to prevent collapse accidents by measuring underground deformation of the slope and the flat surface, and also to predict the collapse of the membrane during construction of the tunnel.

Therefore, the measurement apparatus and method of the second embodiment will be described in detail with reference to an embodiment for constructing a tunnel as follows.

8 is a schematic cross-sectional view showing a state in which the measuring device of the second embodiment according to the present invention is applied to tunnel construction, and FIG. 9 is an enlarged view of portion C of FIG. 8, as shown in FIGS. 4 and 7 to 9. First, underground measurement is possible by embedding in the ground of the circular sensor rod (1) in the tunnel of the tunnel.

In performing the underground measurement, when the ground changes inside the membrane, the circular sensor rod 1 embedded in the ground of the membrane causes deformation.

Therefore, at the moment when the circular sensor rod 1 is deformed to correspond to the change in the ground, the optical fiber 2 provided in the longitudinal direction at equal intervals on the outer side of the circular sensor line 1 is also deformed together, and thus inside the membrane. It is possible to measure the ground strain.

That is, the control unit 4 recognizes the insertion end of the circular sensor rod as a reference point, calculates the vertical and horizontal deformation directions and the deformation amount for each section of the circular sensor rod 1 including the optical fiber 2, and then the optical fiber ( By converting the vertical and horizontal deformation directions and deformation amounts obtained in each section of 2) into displacement vectors, the deformation direction and change amount of the ground in each section can be calculated.

And based on the deformation direction and the deformation amount of the ground for each section of the circular sensor rod (1), by integrating the deformation direction and the deformation amount of the ground calculated for each section through the controller 4 from one end to the opposite end to the opposite side By being able to calculate the deflection of the end and the deflection of each section, it is possible to calculate the deflection of the circular sensor rod (1) located outward in the ground at the innermost reference point of the circular sensor rod (1).

Therefore, it is possible to promptly predict the collapse of the membrane and take measures such as evacuation of workers.

On the other hand, although the use example has given the construction of the tunnel, the measurement of the underground change of the slope or flat surface can also be performed as described above.

The present invention as described above has the effect of providing an underground deformation measurement method and apparatus capable of widely and extensively measuring three-dimensional underground changes such as slopes, flat surfaces, and tunnel periphery.

In addition, by dividing the circular sensor rod to measure the change of the ground by section to measure the ground deformation by section, it is possible to quickly grasp the signs of the collapse of the ground, thereby preventing accidents caused by the collapse of slopes and tunnel face.

While the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include many such variations.

Claims (11)

Buried (200) a circular sensor rod having a straight optical fiber in a longitudinal direction in a pair of upper and lower pairs and a pair of both sides on the outside; Detecting and collecting a length variation of each optical fiber in real time through a measuring instrument in real time by varying a wavelength of a light source irradiated from a measuring instrument to each optical fiber provided outside the circular sensor rod; Receives the length deformation data of each section of the optical fiber through the controller connected to the measuring instrument, and compares the length deformation of each section of the optical fiber forming a pair of up and down, and calculates the vertical deformation direction and deformation amount of the ground for each section, Comparing the length deformation of each section of the paired optical fiber mutually to calculate the horizontal deformation direction and the deformation amount of the ground for each section, the ground for each section based on the vertical, horizontal deformation direction and the deformation amount of each section Calculating a deformation direction and a deformation amount of 202; Geometry deformation method using an optical fiber sensor, characterized in that consisting of. The optical fiber sensor according to claim 1, wherein the deformation direction and the change amount of the ground for each section are calculated by converting the vertical and horizontal deformation directions and the deformation amount into displacement vectors. Geometry measurement method. The method of claim 1, wherein the calculating of the deformation direction and the deformation amount is performed by integrating the deformation direction and the deformation amount of the ground calculated for each section through the controller to an arbitrary section based on one end. Geometry measurement method using the optical fiber sensor, characterized in that it further comprises the step of calculating the deflection. The method of claim 1, wherein the calculating of the deformation direction and the deformation amount is performed by integrating the deformation direction and the deformation amount of the ground calculated for each section through the controller to the opposite end on the basis of one end. Geometry measurement method using the optical fiber sensor, characterized in that it further comprises the step of calculating. The deflection of each of the sections, according to any one of claims 1 to 4, Geometry measurement method using an optical fiber sensor characterized in that obtained by. A circular sensor rod (1) installed buried in the ground or inside of the structure and provided with a straight optical fiber (2) in a pair of up and down and a pair on both sides; The light source generator 33 for measuring the length deformation of each optical fiber 2 for each section of a predetermined length by varying the wavelength of the light source to each optical fiber 2 of the circular sensor rod 1, and the A measuring unit 3 including a data collector 32 collecting data while measuring the length deformation in real time for each section while irradiating a light source; The length deformation data of each section of each optical fiber 2 collected by the measuring instrument 3 are input, and the length deformation of each section of the optical fiber 2 constituting the upper and lower pairs is compared with each other, and the vertical of the ground for each section is vertical. The deformation direction and the deformation amount are calculated, and the horizontal deformation direction and the deformation amount of the ground for each section are calculated by comparing the length deformation of each section of the paired optical fibers 2, and the vertical and horizontal deformation amounts for each section are calculated. A controller 4 for calculating the deformation direction and deformation amount of the ground for each section based on the result; Earth deformation measuring device using a fiber optic sensor, characterized in that consisting of. The ground deformation measurement using the optical fiber sensor according to claim 6, wherein the controller (4) calculates the deformation direction and the deformation amount of the ground for each section by converting the vertical and horizontal deformation directions and the deformation amount into displacement vectors. Device. delete delete delete delete