CN213089837U - Shock wave soot blower system - Google Patents

Abstract

The utility model discloses a shock wave soot blower system, including the aeration tank, characterized by: the device is characterized by also comprising a through pipe, the middle part of the through pipe is communicated with a tank opening of an inflation tank, one end of the through pipe is detachably connected with a movable pipe communicated with the through pipe, one end of the movable pipe, far away from the through pipe, is in closed arrangement, the other end of the through pipe is communicated with a shock wave emission pipe, a spring is arranged in the movable pipe, one end of the spring is connected with the closed end of the movable pipe, the other end of the spring is provided with a sealing block, the sealing block slides in the through pipe, the sealing block is abutted against the inner peripheral wall of the through pipe, two ends of the spring are connected with a; when the spring resets, the sealing block is located one side of the intersection between the inflation tank and the through pipe, which is far away from the movable pipe. Through adopting above-mentioned setting, have the advantage that improves gas flow velocity, utilize sealed piece to replace leading the diaphragm and improve the air current stability, and increase of service life.

Description

Shock wave soot blower system

Technical Field

The utility model relates to a technical field of shock wave soot blower, concretely relates to shock wave soot blower system.

Background

The shock wave soot blower is a new generation product of a boiler soot removing system and is widely applied to removing soot on a heating surface at the tail part of a boiler. The working principle of the shock wave soot blower is as follows: acetylene and other common combustible gas and air are mixed homogeneously in certain proportion and fed into the combustor for combustion after passing through their flow measuring and controlling systems. The pressure of gas generated by combustion is limited within a certain range, the shock wave energy emitted at the nozzle of the output pipe is adapted to the condition of deposited ash, the deposited ash on the heated surface falls off under the action of the shock wave, and dust particles, loose objects, adhesive objects and sediments on the polluted surface are removed, so that the exhaust gas temperature at the tail part of the boiler is reduced, and the thermal efficiency of the boiler is improved.

The shock wave device of the shock wave soot blower is mostly of a guide diaphragm type structure, a combustion gas filling chamber of the shock wave soot blower is divided into two parts of spaces by a guide diaphragm, and the size of the two parts of spaces divided in the combustion gas filling chamber is changed by moving the two parts of spaces divided in the combustion gas filling chamber by utilizing the flexibility characteristic of the guide diaphragm so as to discharge the gas in the combustion chamber, thereby achieving the soot blowing effect. Because the guide diaphragm is flexible, the mode of gas discharged through the guide diaphragm has a hysteresis phenomenon, the speed of the discharged gas is low, the airflow not only needs to overcome the flexible characteristic of the guide diaphragm, but also needs to overcome the problem of large airflow resistance, and meanwhile, because the guide diaphragm needs to be frequently moved in a telescopic manner, the service life of the guide diaphragm is shortened.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a shock wave soot blower system which can improve the air speed, overcome the flexible problem of the guide film and cause the large problem of air flow resistance and prolong the service life.

The purpose of the utility model is realized through the following technical scheme:

a shock wave soot blower system comprises an inflation tank and a through pipe, wherein the middle part of the through pipe is communicated with a tank opening of the inflation tank, one end of the through pipe is detachably connected with a movable pipe communicated with the through pipe, one end, far away from the through pipe, of the movable pipe is arranged in a closed mode, the other end of the through pipe is communicated with a shock wave emission pipe, a spring is arranged in the movable pipe, one end of the spring is connected with the closed end of the movable pipe, a sealing block is arranged at the other end of the spring, the sealing block slides in the through pipe and is abutted against the inner peripheral wall of the through pipe, two ends of the spring are connected with a power supply with the same current flow direction through a circuit, and a control switch is arranged between the power supply and the spring; when the spring resets, the sealing block is located the inflation jar with one side that the junction was kept away from between the siphunculus the movable tube.

Further, one end of the movable pipe, facing the through pipe, is provided with a threaded connection cap, and one end of the outer peripheral surface of the through pipe, facing the movable pipe, is provided with an external thread for threaded connection of the threaded connection cap.

Further, the outer peripheral surface of the movable pipe is rotatably connected with a plurality of rotating rings along the pipe depth direction, the inner peripheral surface of each rotating ring is rotatably connected with a plurality of balls, the outer peripheral surface of each rotating ring is provided with supporting feet, and the supporting feet are provided with rollers supported on the ground; one end of the movable pipe, which is far away from the through pipe, is fixedly connected with a hexagonal head.

Furthermore, a plurality of working holes are arranged on the peripheral surface of the hexagonal head in a penetrating manner along the circumferential direction; the shock wave soot blower system also comprises a plurality of movable rods which are inserted into the working holes.

Further, the diameter of the outer peripheral surface of one end, close to the through pipe, of the shock wave transmitting pipe is smaller than that of the outer peripheral surface of the through pipe, and a step for abutting the sealing block is formed between the shock wave transmitting pipe and the through pipe.

Furthermore, the side surface of the sealing block facing the shock wave transmitting tube is provided with a conical block which is opposite to the channel of the shock wave transmitting tube, and the tip of the conical block faces the shock wave transmitting tube.

Further, the side of the sealing block facing the closed end of the movable tube is provided with a guide rod, the closed end in the movable tube is fixedly connected with a fixed block, and the side of the fixed block facing the through tube is provided with a slot for the guide rod to be inserted.

And a pushing cylinder is arranged outside one end of the movable pipe, which is far away from the through pipe, the extending end of the pushing cylinder is inserted into the movable pipe, and the extending end of the pushing cylinder penetrates through the slot of the fixed block and then is connected with the guide rod.

Further, the peripheral surface of the sealing block is rotatably connected with a plurality of sliding beads which are abutted against the inner side wall of the through pipe.

The utility model discloses following beneficial effect has:

the utility model provides a shock wave soot blower system, the aeration tank is linked together with the combustion chamber, utilizes the gas that the combustion chamber produced to arrange to the aeration tank in to reach the effect of make-up gas, set up the siphunculus through jar mouth department at the aeration tank, and set up movable pipe and shock transmitting tube respectively at the both ends of siphunculus, because the one end that the shock transmitting tube was kept away from to the movable pipe is and seals the setting, consequently make the gas in the aeration tank can only discharge from the position of shock transmitting tube unidirectionally, thereby realize the effect that gas turns to output. Through set up spring and sealed piece in the movable tube, because the both ends of spring pass through the unanimous electric current of flow direction with the circuit through the power, according to the electricity and magnetism principle, the magnetic pole direction of each circle coil of spring is unanimous, thereby make the adjacent coil of spring be close to each other, reach compression spring's effect, otherwise stop to let in the electric current to the spring both ends through control switch, make the spring reset and drive sealed piece and remove to one side that the movable tube was kept away from to the junction between gas charging tank and the siphunculus, utilize the global inner peripheral surface butt with the siphunculus of sealed piece, in order to reach sealed siphunculus, reduce the gas in the gas charging tank and arrange. Meanwhile, when the spring is in a natural state, the gas in the inflation tank is continuously filled, and the whole volume formed by sealing the inflation tank, the through pipe and the movable pipe by the sealing block keeps dynamic balance, so that the gas in the inflation tank is continuously compressed, the stored energy of the inflation tank is continuously increased, when the two ends of the spring are electrified by a power supply, the spring is contracted, the sealing plate is driven to move to the intersection between the inflation tank and the through pipe, the gas in the space sealed by the sealing plate is rapidly discharged to the shock wave transmitting pipe, according to the energy conservation law, when the energy of the compressed gas is larger, the flow velocity of the gas when the gas is discharged to the shock wave transmitting pipe is higher, and the effect of rapidly cleaning dust on the heating surface of the boiler is achieved; compared with the prior art, sealed piece is used for replacing and leads the diaphragm and realize the exhaust function, because sealed piece is made by hard material, need not change space volume size through utilizing self flexibility characteristics, is favorable to improving the stability that gas flows to the life of extension sealed piece, and overcome effectively and led the flexible problem of diaphragm and arouse the big problem of air current resistance.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is an exploded view of the present invention.

Fig. 3 is a cross-sectional view of the present invention.

In the figure: 1. an inflation tank; 2. pipe passing; 21. an external thread; 22. a step; 3. a shock wave emitting tube; 4. a movable tube; 41. a hexagonal head; 411. a working hole; 42. a fixed block; 421. a slot; 43. a threaded connection cap; 5. a spring; 51. a sealing block; 52. a sliding bead; 53. a conical block; 54. a guide bar; 6. a rotating ring; 61. supporting legs; 62. a roller; 63. a ball bearing; 7. a supporting seat; 8. a movable rod; 81. a movable head; 9. the cylinder is pushed.

Detailed Description

The present invention will be described in further detail with reference to the following drawings and specific embodiments. In the present specification, the terms "upper", "inner", "middle", "left", "right" and "one" are used for convenience of description, and are not intended to limit the scope of the present invention, and the relative relationship between the terms and the corresponding parts may be changed or adjusted without substantial technical changes.

Example 1:

referring to fig. 1 to 3 show a shock wave soot blower system, including the aeration tank 1 that jar mouth set up down, the jar mouth intercommunication of aeration tank 1 has siphunculus 2, the outer peripheral face of siphunculus 2 is linked together along the jar mouth of its pipe depth direction with aeration tank 1, the pipe depth direction of siphunculus 2 sets up with the jar body height mutually perpendicular of aeration tank 1, the pipe depth direction of siphunculus 2 is on a parallel with ground, the one end of siphunculus 2 can be dismantled and be connected with the movable pipe 4 that is linked together with siphunculus 2, the internal perisporium of movable pipe 4 and the internal perisporium coplane setting of siphunculus 2, the one end that siphunculus 2 was kept away from to movable pipe 4 is sealed the setting, the other end intercommunication of siphunculus 2 has shock. Install spring 5 in the movable tube 4, the one end of spring 5 and the blind end fixed connection of movable tube 4, the axis of spring 5 and the coaxial setting of axis of movable tube 4, spring 5's the other end inlays to be established and is fixed with seal block 51, seal block 51 is the setting of cylinder form, seal block 51 is made by hard material, stronger intensity and toughness have, seal block 51's axis and the coaxial setting of axis of movable tube 4, seal block 51 slides along the deep direction of the pipe of siphunculus 2 in siphunculus 2, seal block 51's outer peripheral face diameter slightly is less than the diameter of siphunculus 2 and movable tube 4's internal perisporium, seal block 51's outer peripheral face rotates along its circumference direction and is connected with the slip pearl 52 of round and siphunculus 2 inner wall or movable tube 4 inner wall. The two ends of the spring 5 are connected with a power supply (not shown in the figure) with the same current flow direction through a line, and the line between the power supply (not shown in the figure) and the spring 5 is connected with a control switch (not shown in the figure) for controlling the power supply (not shown in the figure) to be turned on and turned off.

Referring to fig. 1 to 3, a threaded connection cap 43 is integrally connected to one end of the outer peripheral surface of the movable tube 4 facing the through tube 2, a connection end of the threaded connection cap 43 protrudes from an end surface of the movable tube 4 facing the through tube 2, and an external thread 21 for threaded connection of the threaded connection cap 43 is provided on one end of the outer peripheral surface of the through tube 2 facing the movable tube 4. The outer peripheral surface of activity pipe 4 all rotates along its pipe depth direction's both ends and is connected with swivel 6, and the inner peripheral surface of swivel 6 distributes along its ring direction has a round ball 63, and ball 63 rotates with the inner wall of swivel 6 and is connected, and ball 63 and the outer peripheral surface butt of activity pipe 4, the outer peripheral surface fixedly connected with of swivel 6 two supporting legs 61 that set up down, and the one end rotation of supporting leg 61 towards ground is connected with the gyro wheel 62 that supports in ground.

The moving tube 4 is kept away from the closed end face fixedly connected with hexagonal head 41 of siphunculus 2, and hexagonal head 41's cross section personally submits regular hexagon setting, and hexagonal head 41 presss from both sides tightly and rotates moving tube 4 in order to reach the effect of installation or dismantlement moving tube 4 for the spanner, and the axis of hexagonal head 41 sets up with the axis is coaxial of moving tube 4. The adjacent three sides of hexagonal head 41 all link up there is work hole 411, and wherein two work holes 411 are pegged graft and are had movable rod 8, and the one end that work hole 411 was kept away from to movable rod 8 is provided with movable head 81.

Specifically, because the both ends of spring 5 need siphunculus 2 circuit access power (not shown in the figure), sealed piece 51 is because long-term reciprocating motion simultaneously, in the motion process, when discharge gas, sometimes because carminative velocity of flow is too big, in aeration tank 1 can arrange some dusts in the combustion chamber to aeration tank 1, siphunculus 2 and movable tube 4, and cause the pollution, pile up for a long time and can cause the condition such as pipeline jam. Therefore, through the external screw thread 21 threaded connection who sets up screw cap and siphunculus 2, rotate the butt through the ball 63 that sets up movable pipe 4 and swivel becket 6 to reduce the frictional force that produces among the rotational motion process, thereby realize that movable pipe 4 rotates around its axis, and dismantle movable pipe 4 with the installation through rotating movable pipe 4, make the dismouting of movable pipe 4 easy and simple to handle.

Meanwhile, the hexagonal head 41 is arranged for a wrench to clamp the hexagonal head 41 and then rotate the movable tube 4, so that the movable tube 4 is convenient to rotate; because the volume of the movable tube 4 is great in reality, for the convenience of further improvement operation, through set up work hole 411 at the outer peripheral face of hexagonal head 41, utilize the movable rod 8 to insert wherein in two relative work holes 411, through the activity head 81 that rotates two movable rods 8 around the axis of movable tube 4 to rotate movable tube 4, because movable rod 8 is small, length is less, and the quality is lighter, can further improve the convenience of operation. Through setting up supporting legs 61 and gyro wheel 62, make the easy and simple to handle of transport activity pipe 4, make activity pipe 4 and siphunculus 2 separation, the dust impurity in the people's clearance activity pipe 4 of being convenient for and siphunculus 2.

Referring to fig. 1 to 3, the diameter of the outer peripheral surface of one end of the shock wave transmitting tube 3 close to the through pipe 2 is smaller than that of the outer peripheral surface of the through pipe 2, the axis of the shock wave transmitting tube 3 is coaxial with that of the through pipe 2, and the intersection between the shock wave transmitting tube 3 and the through pipe 2 is provided with a step 22 for the sealing block 51 to abut against and limit. The intersection between shock wave launching tube 3's internal perisporium and siphunculus 2 inner wall is the chamfer setting, sealed piece 51 is towards shock wave launching tube 3's side fixedly connected with awl piece 53, the axis of awl piece 53 and the coaxial setting of sealed piece 51's axis, the most advanced of awl piece 53 sets up towards shock wave launching tube 3, the tapering of awl piece 53 is unanimous with the inclination of shock wave launching tube 3 and siphunculus 2 right angle chamfer, when the step 22 butt of intersection between sealed piece 51 and shock wave launcher and siphunculus 2, the chamfer butt of intersection between the outer peripheral face of awl piece 53 and shock wave launching tube 3 and the siphunculus 2.

Specifically, the step 22 is arranged at the intersection between the shock wave transmitting tube 3 and the through tube 2, when the spring 5 is reset to be in a natural state or a stretching state, when the gas charging tank 1 is filled with gas to push the sealing plate to move towards the shock wave transmitting tube 3, the sealing block 51 is abutted against the step 22 by utilizing the limiting effect of the step 22, the situation that the spring 5 is continuously stretched to overcome the yield point to cause the damage of the spring 5 is favorably reduced, and therefore the service life of the spring 5 is favorably prolonged; through setting up awl piece 53 and chamfer, when sealed piece 51 and step 22 butt, utilize awl piece 53 and chamfer butt to further increase the area of contact between sealed piece 51 and awl piece 53 and siphunculus 2 and the shock wave launching tube 3, with the gas in improving the sealed gas-filled tank 1 between sealed piece 51 and the awl piece 53, reduce the condition that the gas in the gas-filled tank 1 leaked.

Referring to fig. 1 to 3, a guide rod 54 is fixedly connected to a side surface of the sealing block 51 facing the closed end of the movable tube 4, an axis of the guide rod 54 is coaxial with an axis of the movable tube 4, a fixed block 42 is fixedly connected to a side surface of the closed end of the movable tube 4 facing the movable tube 4, the fixed block 42 is arranged in a cylindrical shape, a slot 421 for the guide rod 54 to be inserted and limited is formed in the side surface of the fixed block 42 facing the through tube 2, the length of the guide rod 54 along the rod length direction is equal to the depth of the slot 421 along the slot depth direction, and the length of the guide rod 54 along the rod length direction is slightly greater than the length of.

Specifically, the guide rod 54 is inserted into the slot 421 of the fixing block 42, so that the guiding performance of the reciprocating motion of the sealing block 51 is improved, the bending deformation of the spring 5 in the process of performing the telescopic motion is reduced, and the telescopic motion of the spring 5 is stable.

Referring to fig. 1 to 3, the end surface of the movable tube 4 away from the through tube 2 is additionally connected with a pushing cylinder 9 through a screw lock, the pushing cylinder 9 is a hydraulic cylinder or a pneumatic cylinder, the extending end of the pushing cylinder 9 is inserted into the movable tube 4, and the extending end of the pushing cylinder 9 penetrates through the slot 421 of the fixed block 42 and then is fixedly connected with the end surface of the guide rod 54 facing the slot 421.

Specifically, the pushing cylinder 9 is connected to the guide rod 54 after penetrating through the slot 421 of the fixing block 42, and the pushing cylinder 9 is used to directly control the guide rod 54 to perform front and rear telescopic movement, so as to directly control the telescopic movement of the spring 5, thereby further improving the stability of the telescopic movement of the spring 5.

During the use, when stopping to let in the electric current to the both ends of spring 5 through control switch, spring 5 resets, promote the closing plate to the direction motion of being close to shock wave launching tube 3, to sealed piece 51 and siphunculus 2 step 22 butt that is close to shock wave launching tube 3, utilize the chamfer butt of awl piece 53 and siphunculus 2 simultaneously, with further sealed gas charging tank 1, siphunculus 2 and movable tube 4, make the volume of three keep unchangeable simultaneously, because constantly having gaseous emission in the gas charging tank 1, under the unchangeable condition of space volume, make gas constantly compressed, the energy of storage also increases along with it. On the contrary, when the pushing cylinder 9 is in a pressure relief state, the extending end of the pushing cylinder 9 can freely stretch and contract, the control switch is started, current in the same direction flows into two ends of the spring 5 in a row, the spring 5 integrally generates current in the same direction, according to the electromagnetic principle, each turn coil of the spring 5 is equivalent to a magnet with the same magnetic pole direction, so that the spring 5 realizes contraction movement, the sealing block 51 is driven to move in the direction far away from the shock wave transmitting tube 3, the space of the sealing block 51 close to one side of the movable tube 4 is compressed, simultaneously, the energy of the gas in the inflation tank 1 is increased, when the sealing block 51 moves to the intersection between the inflation tank 1 and the through tube 2, the gas in the inflation tank 1 and the movable tube 4 is discharged to the shock wave transmitting tube 3 from the gap position between the sealing block 51 and the inflation tank 1, according to the law of conservation of energy, the compressed gas in the inflation tank 1 is converted into kinetic energy and quickly discharged to the shock wave transmitting tube 3, the flow velocity of the gas is improved, and the soot blowing effect on the heating surface of the boiler is realized.

Example 2:

example 2 differs from example 1 in that:

the intersection between shock wave launching tube 3's internal perisporium and siphunculus 2 inner wall is the chamfer setting, sealed piece 51 is towards the side fixedly connected with hemisphere piece (not shown in the figure) of shock wave launching tube 3, the axis of hemisphere piece (not shown in the figure) and the coaxial setting of sealed piece 51's axis, the semicircle face of hemisphere piece (not shown in the figure) sets up towards shock wave launching tube 3, when the step 22 butt of intersection between sealed piece 51 and shock wave transmitter and siphunculus 2, the chamfer butt of intersection between semicircle face and shock wave launching tube 3 and the siphunculus 2 of semicircle piece.

To sum up, aeration tank 1 is linked together with the combustion chamber, utilizes the gas row that the combustion chamber produced to aeration tank 1 in to reach supplementary gaseous effect, set up siphunculus 2 through jar mouth department at aeration tank 1, and set up movable pipe 4 and shock transmitting tube 3 respectively at siphunculus 2's both ends, because movable pipe 4 keeps away from the one end of shock transmitting tube 3 and is sealed the setting, consequently make the gas in aeration tank 1 can only discharge from the position of shock transmitting tube 3 unidirectionally, thereby realize the effect that gas turned to output. Through set up spring 5 and seal block 51 in movable tube 4, because the both ends of spring 5 pass through the current that the flow direction is unanimous through power and circuit, according to the electricity magnetism generating principle, the magnetic pole direction of each circle coil of spring 5 is unanimous, thereby make the adjacent coil of spring 5 be close to each other, reach compression spring 5's effect, otherwise stop to spring 5 both ends through control switch and let in the electric current, make spring 5 reset and drive seal block 51 and remove to the one side that the movable tube 4 was kept away from to junction between aeration tank 1 and siphunculus 2, utilize seal block 51's global and siphunculus 2's inner peripheral surface butt, in order to reach sealed siphunculus 2, reduce the condition that the gas in the aeration tank 1 was arranged to shock wave transmitting tube 3.

Meanwhile, when the spring 5 is in a natural state, the gas in the inflator can 1 is continuously filled, and the whole volume formed by sealing the inflator can 1, the through pipe 2 and the movable pipe 4 by the sealing block 51 keeps dynamic balance, so that the gas in the inflator can 1 is continuously compressed, the stored energy of the inflator can 1 is continuously increased, when the two ends of the spring 5 are electrified by a power supply, the spring 5 is contracted, and the sealing plate is driven to move to the intersection between the inflator can 1 and the through pipe 2, so that the gas in the space sealed by the sealing plate is rapidly discharged to the shock wave transmitting pipe 3, according to the law of energy conservation, when the energy of the compressed gas is larger, the flow velocity of the gas when the gas is discharged to the shock wave transmitting pipe 3 is faster, and the effect of rapidly cleaning dust on the heating surface of the boiler is achieved; compared with the prior art, the sealing block 51 is used for replacing the guide diaphragm to realize the exhaust function, and because the sealing block 51 is made of hard materials, the size of the space volume is not required to be changed by utilizing the flexibility characteristic of the sealing block, the stability of gas flow is favorably improved, the service life of the sealing block 51 is prolonged, and the problem that the airflow resistance is large due to the flexibility problem of the guide diaphragm is effectively solved.

The embodiment of the present invention is not limited to this, according to the above-mentioned content of the present invention, the common technical knowledge and the conventional means in the field are utilized, without departing from the basic technical idea of the present invention, the present invention can also make other modifications, replacements or combinations in various forms, all falling within the protection scope of the present invention.

Claims (9)

1. The shock wave soot blower system comprises an inflation tank and is characterized in that: the device is characterized by further comprising a through pipe, the middle of the through pipe is communicated with a tank opening of the inflation tank, one end of the through pipe is detachably connected with a movable pipe communicated with the through pipe, one end, far away from the through pipe, of the movable pipe is arranged in a closed mode, the other end of the through pipe is communicated with a shock wave emission pipe, a spring is arranged in the movable pipe, one end of the spring is connected with the closed end of the movable pipe, a sealing block is arranged at the other end of the spring, the sealing block slides in the through pipe, the sealing block is abutted against the inner peripheral wall of the through pipe, power supplies with consistent current flowing directions are connected to the two ends of the spring through circuits, and a control switch is arranged; when the spring resets, the sealing block is located the inflation jar with one side that the junction was kept away from between the siphunculus the movable tube.

2. The shock sootblower system of claim 1, wherein: the activity pipe orientation the one end of siphunculus is provided with the threaded connection cap, the outer peripheral face orientation of siphunculus the one end of activity pipe is provided with the confession threaded connection cap threaded connection's external screw thread.

3. A shock sootblower system as claimed in claim 2, wherein: the outer peripheral surface of the movable pipe is rotatably connected with a plurality of rotating rings along the pipe depth direction, the inner peripheral surface of each rotating ring is rotatably connected with a plurality of balls, the outer peripheral surface of each rotating ring is provided with supporting legs, and the supporting legs are provided with idler wheels supported on the ground; one end of the movable pipe, which is far away from the through pipe, is fixedly connected with a hexagonal head.

4. A shock sootblower system as claimed in claim 3, wherein: a plurality of working holes are formed in the peripheral surface of the hexagonal head in a penetrating manner along the circumferential direction; the shock wave soot blower system also comprises a plurality of movable rods which are inserted into the working holes.

5. The shock sootblower system of claim 1, wherein: the diameter of the outer peripheral surface of one end, close to the through pipe, of the shock wave transmitting pipe is smaller than that of the outer peripheral surface of the through pipe, and a step for abutting the sealing block is arranged between the shock wave transmitting pipe and the through pipe.

6. The shock sootblower system of claim 5, wherein: the side face, facing the shock wave transmitting tube, of the sealing block is provided with a conical block which is right opposite to a channel of the shock wave transmitting tube, and the tip of the conical block faces the shock wave transmitting tube.

7. The shock sootblower system of claim 1, wherein: the sealed piece orientation the side of activity pipe blind end is provided with the guide bar, blind end fixedly connected with fixed block in the activity pipe, the fixed block orientation the confession has been seted up to the side of siphunculus the slot that the guide bar was pegged graft.

8. The shock sootblower system of claim 7, wherein: a pushing cylinder is arranged outside one end, far away from the through pipe, of the movable pipe, the extending end of the pushing cylinder is inserted into the movable pipe, and the extending end of the pushing cylinder penetrates through the inserting groove of the fixed block and then is connected with the guide rod.

9. The shock sootblower system of claim 1, wherein: the peripheral face of the sealing block is rotatably connected with a plurality of sliding beads which are abutted against the inner side wall of the through pipe.

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