SU1195798A1 - Versions of linear pneumatic source of seismic signals for water bodies - Google Patents

Abstract

1. LINEAR PNEUMATIC SOURCE OF SEISMIC SIGNALS FOR; AQUATORY (HIS VARIANT) containing interconnected hollow tube emitters with working chambers blocked by movable cylinders and a stop emitter, characterized in that, in order to simplify and increase reliability, the stop organ of the emitter is made in the form of an annular electromagnet and core, which is relatively rigid a cylinder and a pipe cavity with a ring, the outer diameter of which the invention relates to the field of marine seismic surveys, in particular, to the radiators of linear pneumatic sources seismic FIR signal for waters. The purpose of the invention is to simplify and increase the reliability of the source. Figure 1 shows a linear, pneumatic source of seismic signals, the general view; In Figures 2 and 3, the variants of the locking member of the radiating unit are not less than the inner diameter of the movable cylinder, and the space between the electromagnet and the core communicates with the cavity of the pipe by a channel. 2. The source of seismic signals for water areas, containing radiators connected between, by a hollow pipe with working chambers blocked by movable cylinders, and an emitter closure body, which is also distinguished by the fact that, in order to simplify and improve reliability, the emitter closure body is ring-shaped electromagnet and a spring-loaded core placed inside a sealing, mobile, a "5 cylinder sealing ring, under (L springed relative to the electromagnet and provided with a ledge located under korema with a gap relative to him. The source of seismic signals for water areas according to claim 2 is about the fact that, in order to increase durability, the sealing ring is equipped with a protective sleeve; o 00 The seismic source consists of flexible hollow tube I (performs at the same time the role of a tugboat and the role of a compressed air receiver) with coupling joints 2, radiators 3 with adapters 4 and clamps 5, electrical communications 6 (control and operation cables of radiators) The radiator 3 is filled in the form of a hollow body 7 with channel 8. a housing 7 has shaped pistons 9 and 10

Description

1 annular groove 11 and channel 12 "On pistons 9 and 10, a cylinder 13c is mounted for movement with an annular axis 14 and an annular groove 15 °. A cavity g formed by pores 9 and 10 is a control chamber, and a cavity formed by body 7 and cylinder 13 - working chamber. In adapter 4 (FIG. 2), channel 16 is made and electromagnet 17 is placed, in its case channel 8 is made. Above electromagnet 17 ring-shaped bark 19 with sealing rings 20-22 is placed with movement, resting against travel stop 23o Electro The magnet 17 and the ring-shaped bark 19 form a shut-off organ of the radiator. A variant of the shut-off organ, shown in FIG. 3, consists of a combination of rings 22, 20, a spring 24 and a protective sleeve 25 partially setting under the bark 26 with a spring 27. The source works as follows Compressed air from the compressor (not shown) enters the flexible hollow tube 1, fills the entire volume formed by the hollow housings 7 and tube 1 and simultaneously into the channels 8, 12, 16 and 18 (cofigo and 2) of the radiator Zo Under the action of compressed air received through the channels 16 and 18 (smo figo2), ring Measles 19 moves upward to limiter 23 (mofigo2) o Through channels 8 and 12, compressed air enters the control chamber of the radiator 3 and, acting on the stage (see figure 14 formed by the difference in diameters of the cylinder 13 and the annular flow 14, lowers the cylinder 13 down until it stops in adapter 4 and seals cylinder 13 and ring 22 Compressed air from control chamber along annular groove 15 enters the working chamber. When the diameters of the cylinders 13 and ring 20 are equal, their radial seal takes place. As the diameter of ring 20 increases, the excess force from the sides s core 19 will be transmitted to the stroke limiter 23 to p 19 (figo2). At fiGoZ the cylinder 13 and the ring 22 are sealed by moving the ring 22 by a spring force of 24 °. When the pressure inside the source reaches 0.1-0.2 MP, all the working chambers of the radiators are closed and sealed. The source is lowered into water, the pressure is adjusted working, after which it is ready to operate. Emitters can be triggered simultaneously or with delays according to a pre-planned CODU. The distance between the emitters is selected depending on their working volume and pressure. agnite 17 (smofig 2) attracts ring-shaped measles 19, on which rings 20, 21 and 22 are rigidly fixed, cylinder 13 moves upwards, exhaust from the working chamber occurs. Friction force of ring 20, sealing pipe 1, the pipe can be reduced by reducing the diameter rings 20 With a radial seal, when matched a Ie diameters of cylinder 13 and ring 22, the force of friction between cylinder 13 and ring 22 can also be compensated for by the force acting on the side of the working chamber to measles 19 Therefore, the electromagnet 17 may have a small pull gone The compressed air from the working chamber, the measles 19, goes down or rests against the travel stop 23 with a force determined by the diameter of the ring 20, the core 19 and the pressure difference above the crust 19 and below it. The cylinder 13 brakes at the top of the control chamber 14a, and returns to its original position due to the pressure force of compressed air and the difference in diameters of the cylinder 13 in the control chamber. At the same time, compressed air begins to flow into the working chamber through an annular groove of 15o. The radiator operation cycle is over. The variant of the locking member shown in figoZ works as follows. Electromagnet 17 is equipped with a spring-loaded ring-shaped crust 26, between which the lower plane and the yoke 25 there is a gap 28 when an electric pulse is applied to the electromagnet 17, the measles 26 compresses the spring 27 and acquires kinetic energy at the gap 28. A sharp blow to the holder 25 depressurizes the working chamber 5 by count zu 22 and the cylinder 13 of the future work of the radiator occurs by the scheme described above.

The anchor 26 returns to its original position due to the spring 27, in this case there is a more dramatic triggering of the radiator and a smaller variation in the response time, which is important dp low-volume radiators when forming the total signal

The use of the described invention will simplify the pneumatic sources of seismic signals, improve the stability and reliability of their work, which is especially important for low-volume radiators.

Claims (1)

1. LINEAR PNEUMATIC SOURCE OF SEISMIC SIGNALS FOR AQUATORIES (ITS OPTIONS), comprising emitters interconnected by a hollow pipe with working chambers blocked by movable cylinders and an emitter shut-off element, characterized in that, in order to simplify and increase reliability, the emitter shut-off element is made into in the form of an annular electromagnet and an armature sealed with respect to the movable cylinder and the pipe cavity by a ring, the outer diameter of which