KR101296667B1 - Geophone shieding device for acoustic wave inspection - Google Patents

Abstract

PURPOSE: A geophone protective gear for elastic wave exploration is provided to improve reliability by preventing electrical malfunction in case of rain or after in case of rain or a measured value error of an elastic wave. CONSTITUTION: A receiving body (11) is exposed by being connected with a geophone cone which is inserted into an earth surface in order to receive an elastic wave which is artificially generated. A connecting cable (15) is electrically connected with an elastic wave exploration cable which is connected from a reception recording device. A protecting cap has an opened lower part and a sealed ceiling surface in order to cover a receiving body of a geophone and is fixed on the earth surface. Both ends of a cable support are fixed to the inner surface of the protecting cap in order to be separated as a constant height from the earth surface corresponding to an inner space of the protecting cap.

Description

Geophone Shieding Device for Acoustic Wave Inspection

The present invention relates to a device for protecting a geophone used in the seismic survey from the external environment, and more particularly, to prevent a signal recognition error of the seismic wave due to rainwater and strong winds that are encountered frequently in the field, and the seismic probe The present invention relates to a seismic probe geophone protection device that can prevent rainwater from penetrating into the connection portion between the geophone connection cable and the reception failure due to disturbance around the geophone.

In general, seismic survey using geophone is mainly used for the ground survey.

Such a seismic detection method, as shown in Figure 1, the geophone 10 is inserted into the body portion on the ground surface, the receiving and recording device 30 and the gunpowder in the land connected to the elastic wave detection cable 20 of a certain length The seismic wave generating system 40 which artificially generates seismic waves through an explosion or a blow using a hammer is used.

That is, the seismic waves, which are artificially generated by the seismic wave generation system 40, are refracted and reflected in various layers such as soil layers, weathering zones, soft rocks, and hard rock layers below the ground surface, and then received and received by the geophone 10. The information about the geological structure can be obtained by analyzing the propagation time and the waveform of the received acoustic waves by being transmitted to the recording device 30.

Information about the geological structure obtained through the seismic exploration method can be used to determine a variety of geological structures, such as civil engineering, groundwater exploration, oil exploration, or the study of the global crustal structure.

On the other hand, the geophone (geophone) is installed on the ground surface for the ground survey to be connected to the cone-shaped geophone cone 12 is inserted into the ground a certain depth, the receiver 11 receiving the acoustic wave signal therefrom and the elastic wave detection cable It consists of a connecting cable 15 extending from the receiver.

Korean Patent Registration No. 10-12227927 (January 30, 2013) discloses a removable geophone in a slide method that prevents measurement errors that may occur due to a weakening of the grip between the geophone cone and the ground, and facilitates accurate seismic measurement. Doing.

However, such a geophone 10 is installed on the ground surface of the open air in order to receive the elastic waves transmitted from the ground surface is exposed to the external environment, when the weather conditions, such as rainy weather and strong wind, deteriorate, measuring the acoustic wave by rain and wind It becomes impossible or difficult.

That is, during rainy weather, it is difficult to identify signals between the seismic waves detected by the geophones and the rainwater that strikes the geophones and the ground surface, resulting in increased errors, and the connection between the seismic probe cable and the connecting cable approaches the ground surface, resulting in rainwater or As rainwater remaining on the surface of the rainy weather penetrates into the connection part, it is difficult to obtain an electrical signal or a malfunction occurs.

In addition, during strong winds, the noise effect caused by the wind is sensed by the geophone, so that the identification of the signal is inaccurate, and various forms of grass, fallen leaves, branches, etc. scattered around the geophone due to wind and strong winds. Fine movements of the same object were measured as noise, reducing the reliability of the seismic detection method.

The present invention is to solve the problems as described above, the object is to prevent the signal recognition error of the seismic wave due to the rainwater and strong winds during the rain, and the rainwater is penetrated into the connection portion between the seismic detection cable and the connection cable. On the other hand, to provide a seismic probe geophone protection device that can prevent the reception failure due to disturbance around the geophone.

Technical problems to be achieved in the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

As a specific means for achieving the above object, the present invention is connected to a geophone cone inserted into the ground surface to receive artificially generated acoustic waves and having a receiver exposed on the ground surface, and the elastic wave detection cable extending from the reception recording device; An apparatus for protecting a geophone having an electrically connected connection cable from an external environment, the apparatus comprising: a protective cap that is opened downward to cover a receiver of the geophone, and has a sealed ceiling surface and is fixed to the ground surface; And a cable supporter fixed at both ends to an inner surface of the protection cap so as to be spaced a predetermined height from the ground surface corresponding to the inner space of the protection cap, wherein the cable support is provided between the lengths of the elastic wave detection cable and the connection It provides a seismic probe geophone protection device characterized in that the connecting terminal connected to the positive and negative terminals of the cable is placed up.

Preferably, the protective cap is provided with an incision so that the elastic wave detection cable having a connection terminal electrically connected to the connection cable of the geophone is introduced into the protective cap and withdrawn from the inside of the protective cap to the outside.

More preferably, both ends of the cable support are fixed to the locking projection protruding from the inner surface of the protective cap adjacent to the cutout.

More preferably, the cutout includes an arrangement groove into which the elastic wave detection cable is inserted and disposed to minimize the movement of the elastic wave detection cable.

Preferably, the lower end outer edge of the protective cap is provided with a fixing plate in contact with the ground surface to form a plurality of anchor holes through which a plurality of anchor pins that are inserted into a predetermined depth to the ground surface correspondingly.

The present invention as described above has the following effects.

(1) A cable support is provided on the inside of the protective cap covering and protecting the geophone so that the connection terminal of the acoustic wave sensing cable connected to the positive and negative terminals of the connecting cable is placed thereon and spaced apart from the ground surface of the geophone. By connecting the connection terminal electrically connected with the connection cable of the geophone to the cable support, it is possible to improve the reliability and prevent the quality of the exploration data by preventing the electrical malfunction caused by rainwater and the measurement value error of the seismic wave even during rain or rain. have.

(2) By installing a protective cap open to the ground to cover and protect the geophone, it is possible to minimize the influence on the geophone by the strong wind, thereby increasing the reliability of the acoustic wave reception value, and geophone While irregular noise caused by various types of objects in the vicinity can be minimized, an effect of increasing the signal-to-noise ratio and improving reliability is obtained.

1 is a schematic diagram showing a general seismic detection method.
FIG. 2 is an external view illustrating a geophone protection device for acoustic wave surveying according to a preferred embodiment of the present invention. FIG.
3 is an overall configuration diagram showing a seismic surveying geophone protection device according to an embodiment of the present invention.
4 is an exploded view of a protective cap employed in the seismic surveying geophone protection device according to an embodiment of the present invention.
FIG. 5 illustrates a seismic surveying geophone protection device according to an exemplary embodiment of the present invention.
a) a top view
b) bottom view
c) is a cross-sectional view.
6 is an external view showing another form of the seismic surveying geophone protection device according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to include an element does not exclude other elements unless specifically stated otherwise, but may also include other elements.

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

As shown in FIGS. 1 to 5b, the seismic surveying geophone protection device 100 according to a preferred embodiment of the present invention is inserted deeply into the ground to receive artificially generated seismic waves using a seismic wave generating system. Protective cap 110 and a cable support so as to protect the geophone 10 consisting of the geophone cone 12 and the receiver 11 connected to the top and exposed to the ground from the external environment during rain and typhoon 120).

The protective cap 110 is provided in the upper portion of the geophone 10 is opened to the bottom to cover and protect the receiver 11 having a connection cable 15 connected to the elastic wave detection cable 20, the closed The cap member is provided with a ceiling surface and is fixed to each ground surface to which the geophone is installed.

On the outer surface of the protective cap 110, an elastic wave detection cable having a connecting terminal 25 in the middle of the length so as to be electrically connected to the connecting cable 15 extending from the receiver 11 of the geophone 10 ( 20) enters the inside of the protective cap, and is provided with an incision 114 to be drawn out of the protective cap.

Here, the lower end outer edge of the protective cap 110 is inserted into the ground surface to a certain depth so that a plurality of anchor pins 115 through which the plurality of anchor pins 115 correspondingly formed so as to generate anchor anchor force through the ground surface It is provided with a fixed plate 116 in contact with.

The fixing plate 116 is preferably made of a plate that is bent to the outer edge of the protective cap 110 bordering the fold line to be in close contact with the ground surface.

On the other hand, the protective cap 110 is able to withstand from the external environment during heavy rain and rainfall, and is provided with a truncated square pyramid cross-section on the lower part to facilitate folding and sheet metal processing through the fold line as shown in FIG. Although illustrated and described as being limited thereto, various forms of structures capable of covering and protecting the receiver 11 in which the geophone cone 12 is fixed to the ground may be selectively employed.

In addition, the inner surface of the protective cap 110 adjacent to the cutout 114 may be provided with a locking step 112 so that both ends of the cable support 120 is caught and fixed.

Accordingly, the protective cap 110 is firmly fixed to the ground surface by anchor pins so as to cover the receiver of the geophone on the upper surface of the ground where the geophone is installed, thereby affecting the geophone by a strong wind during bad weather. By minimizing this, it is possible to increase the reliability of the acoustic wave reception value, while minimizing irregular noise caused by various types of objects near the geophone.

The cable butt 120 is horizontally fixed at both ends of the locking jaw 112 provided on the inner surface of the protective cap 110 so as to be spaced a predetermined height from the ground surface corresponding to the inner space of the protective cap 110. It consists of one board.

The cable support 120 is provided in the middle of the length of the elastic wave detection cable 20 extending from the recording receiving device for receiving and recording the elastic wave connection portion 25a, respectively connected to the positive and negative terminals of the connecting cable 15; The connection terminal 25 having 25b) is placed upright.

Extending to both ends of the connection terminal 25 to fix the position of the connection terminal 25 while fixing the position of the elastic wave detection cable 20 having the connection terminal 25 on the upper surface of the cable support 120 It is preferable to have a pair of cable fixing pins 122 to which the elastic wave detection cable 20 is fitted.

Here, the left and right ends of the cable support 120 is shown and described as being installed horizontally at a position spaced apart from the ground surface by assembling corresponding to the locking step 112 formed on the inner surface of the protective cap 110, but The left and right ends of the cable butt may be fixed to the protective cap in various ways such as a bolting method or a welding method.

In addition, the inner edge of the cutout 114 enters the inside of the protective cap 110 through the cutout 114 so that the connection terminal provided in the middle of the length can be placed on the cable support 120. It is preferable to include an arrangement groove 114a in which the elastic wave detection cable 20 is disposed so as to minimize the movement of the elastic wave detection cable 20 drawn out of the protective cap 110 through the cutout 114.

Accordingly, the connection terminal 25 which extends from the recording receiving device and is provided for each of the lengths of the elastic wave detection cable 20 so as to be electrically connected to the positive and negative terminals provided in the connection cable 15 of the geophone, respectively. By being mounted on the upper surface of the cable support 120 spaced a certain distance from the ground surface, it is possible to prevent contact with moisture, rainwater that permeates the ground surface during rainy weather or rainy weather, so that the measurement error of the geophone due to moisture can be prevented. In essence, this can reduce errors in the seismic measurements and increase reliability.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

10: geophone 11: receiver
12: geophone cone 15: connection cable
20: elastic wave detection cable 25: connection terminal
110: protective cap 112: locking jaw
114: incision 116: fixed plate
120: cable support 122: cable fixing pin

Claims (5)

A geophone having a receiver connected to a geophone cone inserted into the ground surface to receive artificially generated elastic waves and exposed to the ground surface, and a connection cable electrically connected to the elastic wave detection cable extending from the reception recording apparatus. In a device to protect against
A protective cap which is opened downward to cover the receiver of the geophone and has a sealed ceiling surface and is fixed to the ground surface;
And a cable supporter fixed at both ends to the inner surface of the protective cap so as to be spaced apart from the ground surface corresponding to the inner space of the protective cap by a predetermined height.
The cable support is provided in the middle of the length of the elastic wave probe cable, the connecting terminal connected to the positive and negative terminals of the connection cable, the geosonic wave survey geophone protection device, characterized in that arranged. The method of claim 1,
The protective cap is provided with a cut-out so that the elastic wave detection cable having a connection terminal electrically connected to the connection cable of the geophone is introduced into the protective cap and withdrawn from the inside of the protective cap to the outside. Use geophone protector. The method of claim 2,
The cable support is a seismic probe geophone protection device characterized in that both ends are fixed to the locking projection protruding on the inner surface of the protective cap adjacent to the incision. The method of claim 2,
The cutout is a seismic probe geophone protection device characterized in that it comprises an arrangement groove that the elastic wave detection cable is arranged to minimize the movement of the seismic probe cable. 5. The method according to any one of claims 1 to 4,
The bottom end outer edge of the protective cap formed through a plurality of anchor holes that are coupled to a plurality of anchor pins that are inserted to a certain depth to the ground surface through the elastic wave exploration geophone protection device characterized in that it comprises a fixing plate in contact with the ground surface.

Images