KR101436469B1 - Rapping device for a scale removal of heat exchanger - Google Patents

Abstract

Provided is a rapping device for a heat exchanger which includes a body provided inside a sliding space unit and in which a main hydraulic flow channel discharging hydraulic pressure supplied from the outside is formed; a rapping unit in which one end is disposed to be slidable forward and backward while being inserted into the sliding space unit, and the other end is extended outward from the body; a hydraulic inlet flow channel formed at the body to connect the main hydraulic flow channel and the sliding space unit and introducing partial hydraulic pressure supplied from the main hydraulic flow channel to the sliding space unit; a rear-direction moving flow channel formed at an end of the rapping unit to introduce hydraulic pressure supplied from the hydraulic inlet flow channel to the sliding space unit located in front of the end of the rapping unit so as to move the rapping unit backward; a front-direction moving flow channel formed at the end of the rapping unit to be connected with the hydraulic inlet flow channel to introduce the hydraulic pressure supplied from the hydraulic inlet flow channel to the rear of the end of the rapping unit so as to move the rapping unit back to the front position when the rapping unit is moved backward by the hydraulic pressure supplied from the rear-direction moving flow to the sliding space unit; and a hydraulic outlet flow channel formed at the body to be connected to the sliding space unit to be connected to the rear-direction moving flow channel or the front-direction moving flow channel according to the forward or backward movement of the rapping unit so as to discharge the hydraulic pressure inside the sliding space unit outside the body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blowing device for a heat exchanger,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a striking device for a heat exchanger, and more particularly, to a striking device for a heat exchanger, and more particularly, to a striking device for a heat exchanger that strikes a tube unit in order to periodically remove various deposits such as dust accumulated from multiple tubes of a heat exchanger such as a boiler tube unit ≪ / RTI >

In general, cleaning the outer surface of a heat exchanger tube, such as a boiler tube, from accumulated ashes and other deposits is accomplished by various rapping devices. 1, the striking device includes a shaft 6 rotatably installed on a lower portion of a heat exchanger 1, a shaft 6 on the shaft 6, A plurality of hammers 5 hitting respective tubes in accordance with the rotation of the shaft 6 in a state of being connected to the arm 4; A motor 7 for rotating the motor 6, and the like.

Such a conventional striking device has been widely used because of its simple facility due to the use of a mechanical hammer. However, due to the use of a motor as a driving means, the striking device There is a problem that it is difficult to perform a stable blow with frequent failures.

It is an object of the present invention to provide a striking device for a heat exchanger capable of stable striking even in a high temperature and dusty environment.

The present invention relates to a body having a sliding space inside and having a main hydraulic oil path for discharging the hydraulic fluid from the outside after being supplied with oil from the outside and having one end slidably inserted in the sliding space in a forward and backward direction, A hydraulic oil inflow passage formed in the body so as to connect the main hydraulic fluid passage and the sliding space portion to allow a partial hydraulic pressure supplied through the main hydraulic fluid passage to flow into the sliding space portion, A backward flow path formed at one end of the striking part to allow the hydraulic pressure supplied from the hydraulic inlet flow path to flow into the sliding space part located in front of one end of the striking part to move the striking part to the rear, And is supplied to the sliding space portion through the rearward movement passage When the hitting part is moved backward by the pressure, the hydraulic pressure supplied from the hydraulic inflow passage is connected to the hydraulic inflow passage and flows into the sliding space part located behind the one end of the hitting part to return the hitting part back to the forward position And the front moving passage is connected to the sliding space portion and is connected to the rear moving passage or the front moving passage as it moves forward or backward of the striking portion, And a hydraulic pressure discharge passage for discharging the fluid to the outside of the body.

The hitting portion may include a sliding block disposed to be slidable in the front-rear direction in a state of being inserted into the sliding space portion of the body, and a hitting portion extending outwardly from the body in a state of being connected to the front end portion of the sliding block Rods.

In addition, a pressure-increasing space portion connected to the front movement passage and the rear movement passage is provided at one end of the hitting portion, and a booster valve slidingly moved in the forward and backward direction is mounted on the booster portion, The booster valve is slidably moved in the forward and backward directions on the booster chamber by the oil pressure introduced into the booster chamber through the rearward movement channel so that the movement force of the one end of the booster can be increased on the sliding space of the body.

The pressure regulating valve may include a spool having one end coupled to the body and the other end extended to be disposed in the pressure-increased space portion of the striking portion, and a slidable insertion portion disposed outside the other end of the spool for sliding movement on the pressure- And a valve body provided in the valve body and adapted to allow hydraulic pressure supplied from the rearward flow passage to flow into the booster chamber located in front of the valve body to move the valve body backward, And a valve body formed in the valve body and connected to the forward flow passage when the valve body is moved backward by the hydraulic pressure supplied to the booster pressure space through the after- And then flows into the booster space portion located at the rear of the valve body so that the valve body is moved forward It may include a pre bangjeung pressure flow path to cause movement to the return value.

The front end of the valve body may be engaged when the valve body is moved forward, and the rear end of the valve body may be engaged with the rear end of the valve body, The rear end of the valve body can be hooked when the body is moved backward.

In the striking device for a heat exchanger according to the present invention, the hydraulic pressure supplied from the outside is supplied from the hydraulic inflow passage to the front sliding space through the rear travel passage in a state where the striking portion is slidable in the front-rear direction on the sliding space portion of the body, The hitting portion is moved backward and then the hydraulic pressure of the hydraulic inflow passage is supplied to the rear sliding space portion through the forward movement passage to move the hitting portion forward. At this time, when the striking part is moved forward, the other end of the striking part strikes the striking part of the heat exchanger, so that stable operation is performed even in an environment of high temperature and dust, so that the deposit in the heat exchanger stably falls off.

1 is a structural cross-sectional view showing a conventional striking device for a heat exchanger.
2 is a structural cross-sectional view illustrating a striking device for a heat exchanger according to an embodiment of the present invention.
3 is a cross-sectional view of the hydraulic pressure supply state when the hitting portion shown in Fig. 2 is moved backward.
4 is a cross-sectional view of the oil pressure supply state in the forward movement of the hitting portion shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

2 is a cross-sectional view illustrating a striking device for a heat exchanger according to an embodiment of the present invention. FIG. 3 is a sectional view of the striking portion shown in FIG. 2 when the striking portion is moved backward, FIG. 2 to 4, the striker for a heat exchanger includes a body 100, a striking part 200, a hydraulic inflow passage 300, a rearward movement passage 400, a front movement passage 500, And a flow path 600.

The body 100 is a portion for guiding the striking part 200 to be slidably moved back and forth to be described later. A sliding space 110 is formed in the front side and the rear side of the body 100 so that one end of the striking part 200 can be slidably inserted into the body 100. A hole 111 is formed in the front surface of the body 100 to communicate with the sliding space 110 so that the other end of the striking part 200 can be extended to the outside. Here, one side of the body 100 may be fixedly connected to a floor or a heat exchanger adjacent to a heat exchanger (not shown) to be hit.

A main hydraulic oil path 120 is formed in the body 100 to guide the movement of oil pressure to the outside after being supplied with oil pressure from the outside to the inside. A first flow port 121 is formed at one side of the outer surface of the body 100 to supply the hydraulic pressure to one end of the main hydraulic fluid path 120 in the longitudinal direction. A second flow passage 122 is formed at the other side of the outer surface of the body 100 to discharge the hydraulic pressure to the other longitudinal end of the main hydraulic fluid path 120. Here, the hydraulic pressure introduced through the main hydraulic fluid path 120 may be a high-pressure compressed gas or a fluid.

The striking part 200 is a part which is slidably installed in the front and rear direction on the body 100 through the sliding space part 110 of the body 100 and the penetrating pores 111. When the hydraulic pressure is supplied to the sliding space portion 110 through the hydraulic inflow passage 300 to be described later, the hitting portion 200 slides in the forward and backward direction when the hydraulic pressure is supplied to the hitting portion 200 to collide with the hitting portion 10 of the heat exchanger. . One end of the striking part 200 is slidably inserted into the sliding space part 110 of the body 100 so as to be slidable in the front and rear direction and the other end of the striking part 200 is passed through the hole 100 of the body 100, And protrudes outward from the body 100. The striking part 200 includes a sliding block 210 and a striking rod 220. That is, one end of the striking part 200 is a part of the sliding block 210, and the other end is a part of the striking rod 220.

The sliding block 210 is slidably inserted into the sliding space 110 of the body 100 in the forward and backward directions. Inside the sliding block 210, a pressure-increasing space 211 is formed in the front-rear direction so that the pressure-reducing valve 212 to be described later can be slidably inserted in the front-rear direction. The front and rear fastening protrusions 217 and 218 are formed to protrude in the direction of the pressure-increasing space 211 in the front and rear ends of the sliding block 210, respectively. When the front end of the booster 212 is hung in the forward movement of the booster 212 in the booster chamber 211, the forward latching jaw 217 is moved forward by the forward movement force of the sliding block 210 . When the rear end of the booster 212 is engaged with the rear end of the booster 210 in the backward movement of the booster 212 in the booster chamber 211, .

Here, when the hydraulic pressure flows into the booster chamber 211 through the backward movement passage 400 or the front movement passage 500 to be described later, the booster valve 212 rotates in the forward and backward directions The sliding block 210 of the striking part 200 is moved in a correspondingly sliding manner so that the sliding block 210 of the striking part 200 is moved on the sliding space part 110, Thereby increasing the initial moving force of the motor. That is, the booster valve 212 is connected to the first hitting portion 200 so that the sliding block 210 of the hitting portion 200 can be stably moved rearward through the hydraulic pressure supplied through the rear movement passage 400. [ So that the hydraulic pressure can be stably supplied to the sliding space part 110 located in front of the sliding block 210. [ In addition, the booster valve 212 is connected to the first hitting portion 200 so that the sliding block 210 of the hitting portion 200 can be stably moved forward through the hydraulic pressure supplied through the forward movement flow path 500, So that the hydraulic pressure can be stably supplied to the sliding space portion 110 located behind the sliding block 210. [0053] The booster valve 212 includes a spool 213, a valve body 214, a backpressure passage 215, and a throttle passage 216.

The spool 213 guides the valve body 214 in the forward and backward directions on the pressure-increasing space 211 inside the sliding block 210. At this time, the spool 213 is installed on the central axial line of the booster chamber 211 in the front-rear direction. That is, one end of the spool 213 in the longitudinal direction is coupled to the inside of the body 100 located behind the sliding space portion 110. The other end in the longitudinal direction of the spool (213) is extended to be disposed in the pressure-increasing space portion (211).

The valve body 214 is slidably inserted into the pressure-increased space portion 211. That is, the valve body 214 is disposed in the pressure-increased space portion 211 in a state of being slidably inserted outside the other end in the longitudinal direction of the spool 213 so as to slide in the back-and-forth direction on the pressure-increased space portion 211 do.

The back pressure oil passage 215 guides a part of the hydraulic pressure supplied through the backward movement oil passage 400 to be introduced into the pressure-increasing space portion 211 located in front of the valve body 214, So that the valve body 214 can be moved backward on the booster chamber 211 by hydraulic pressure. The rear pressure relief passage 215 is formed at the front end of the valve body 214. More specifically, one end of the rear pressure relief passage 215 is disposed on the front portion of the valve body 214, 214, respectively.

The pressurization pressure passage 216 guides a part of the hydraulic pressure supplied through the forward movement passage 400 to be introduced into the pressure-increasing space portion 211 located behind the valve body 214, So that the valve body 214 can be moved forward in the pressure-increasing space portion 211 by the hydraulic pressure. That is, when the valve body 214 is moved backward by the hydraulic pressure supplied to the pressurized space portion 211 through the after-rupture pressure passage 215, 400 to receive the hydraulic pressure from the forward movement flow passage 400 and then guide the flow of the hydraulic fluid into the pressure increase space portion 211 located behind the valve body 214. The proximal pressure passage 216 is formed at the rear end of the valve body 214. More specifically, one end of the valve body 214 is disposed on the rear portion of the valve body 214, As shown in Fig.

The hydraulic pressure supplied through the rear movement passage 400 to be described later is transmitted to the sliding block 210 of the striking part 200 through the rear pressure passage 215. [ The valve body 214 is further moved to the rear side in a state where the valve body 214 is hooked on the forwardly engaging jaw 217 on the pressurized space portion 211 while being further supplied to the inner pressure- The rearward movement force on the sliding space portion 110 is increased. In addition, the hydraulic pressure supplied through the forward movement flow path 500 to be described later is further supplied to the inside pressure increasing space portion 211 of the sliding block 210 of the hitting portion 200 through the pre-pressurization pressure flow path 216 The valve body 214 moves forward in a state where the valve body 214 is hooked on the rear engagement step 218 on the pressurizing space part 211 and the forward movement force of the sliding block 210 on the sliding space part 110 .

The striking rod 220 is moved to the striking target portion 10 of the heat exchanger while the reciprocating force of the sliding block 210 sliding in the sliding space portion 110 of the body 100 is blown . One end of the striking rod 220 is fixedly coupled to the front surface of the sliding block 210 while the other end of the striking rod 220 is coupled to the front end of the sliding block 210, 111 to the outside of the body 100. The other end of the striking rod 220 is disposed adjacent to the striking object portion 10 of the heat exchanger and repeatedly collides with the striking object portion 10 when the sliding block 210 reciprocates in the forward and backward direction of the sliding block 210 do.

The hydraulic inflow passage 300 guides a part of the hydraulic pressure supplied from the outside through the main hydraulic fluid passage 120 to the sliding space portion 110 of the body 100. That is, the hydraulic oil inflow passage 300 allows the hydraulic pressure supplied to the main hydraulic oil passage 120 to be supplied to the rearward movement passage 400 and the front movement passage 500 to be described later. The hydraulic oil inflow passage 300 is formed at one side of the body 100 and is disposed to connect the main hydraulic fluid passage 120 and the sliding space portion 110. That is, one end of the hydraulic oil inflow passage 300 in the longitudinal direction is connected to the main hydraulic oil passage 120, and the other end is formed inside the body 100 to be connected to the sliding space portion 110.

The rearward movement passage 400 guides the hydraulic pressure supplied to the hydraulic oil inflow passage 300 through the main hydraulic fluid passage 120 to the sliding space portion 110 so that the sliding block 110 slides (210) is moved backward in the sliding space portion (110). That is, the rearward movement flow passage 400 allows the hydraulic pressure supplied from the hydraulic pressure inflow passage 300 to flow into the sliding space portion 110 located in front of the sliding block 210 of the striking portion 200. The rearward movement passage 400 is formed at the front end of the sliding block 210 of the striking part 200. More specifically, one end of the rearward movement passage 400 is disposed at the front of the sliding block 210, Is formed on the front end of the outer circumferential surface of the sliding block 210.

The front movement passage 500 guides the hydraulic pressure supplied to the hydraulic oil inflow passage 300 through the main hydraulic fluid passage 120 to the sliding space portion 110 so as to guide the hydraulic pressure to the sliding block portion 110, (210) is moved forward in the sliding space portion (110). The sliding block 210 of the striking part 200 is moved in the sliding space part 110 by the hydraulic pressure supplied to the sliding space part 110 through the rear moving path 400. [ The sliding space part (200) which is located behind the sliding block (210) of the striking part (200) is connected to the hydraulic inflow path (300) and moves from the hydraulic inflow path 110). The front movement path 500 is formed at the rear end of the sliding block 210 of the striking part 200. More specifically, one end of the sliding block 210 is disposed on the rear part of the sliding block 210, And is disposed at the rear end of the outer circumferential surface of the sliding block 210.

The hydraulic pressure discharge passage 600 is formed in the sliding space 210 of the striking part 200 so as to prevent the rear moving passage 400 or the front moving passage 500 from moving forward or backward, And guides the oil pressure inside the sliding space part 110 to be discharged to the outside of the body 100. That is, the hydraulic pressure discharge passage 600 is connected to the front movement passage 400 in a state where the hydraulic pressure supply passage 300 is connected to the rear movement passage 400, so that the sliding block 210 The hydraulic pressure of the sliding space portion 110 located behind the sliding block 210 is discharged to the outside of the body 100. [ The hydraulic pressure drainage passage 600 is connected to the rearward flow passage 400 in a state where the hydraulic pressure drainage passage 600 is connected to the front movement passage 500, The hydraulic pressure of the sliding space portion 110 located in front of the sliding block 210 is discharged to the outside of the body 100 when the sliding block 210 is moved forward. The hydraulic pressure discharge passage 600 is formed in the body 100 to be connected to the sliding space 110. More specifically, one end of the hydraulic pressure discharge passage 600 is connected to the outside of the body 100, And is formed inside the body 100 to be connected to the body 110.

The sliding block 210 of the striking part 200 is moved forward in the sliding space part 110 by the striking part of the striking part of the heat exchanger, The movement from the state of being moved to the rear side will be described with reference to FIG. That is, the external hydraulic pressure supplied through the main hydraulic oil path 120 is supplied to the sliding space part 110 through the hydraulic oil inflow pathway 300. At this time, the hydraulic pressure supplied through the hydraulic inflow passage 300 is supplied to the sliding space part 110 located in front of the sliding block 210 through the rear travel path 400, And is pushed to move backward in the sliding space portion 110. The hydraulic pressure supplied to the sliding space portion 110 through the rearward movement passage 400 is transmitted to the sliding block 210 located in front of the valve body 214 through the rear pressure passage 215, The valve body 214 may be moved rearward to increase the initial backward movement force of the sliding block 210. [ The hydraulic pressure is discharged to the outside of the body 100 through the hydraulic pressure discharge passage 600 on the sliding space portion 110 located behind the sliding block 210 of the hitting portion 200, 210 can be stably moved backward.

The forward movement of the sliding block 210 of the striker 200 in a state in which the sliding block 210 is moved backward will now be described with reference to FIG. That is, the external hydraulic pressure supplied through the main hydraulic oil path 120 is supplied to the sliding space part 110 through the hydraulic oil inflow pathway 300. At this time, the hydraulic pressure supplied through the hydraulic inflow passage 300 is supplied to the sliding space part 110 located behind the sliding block 210 through the front movement path 500, and the sliding block 210 And is pushed forward in the sliding space part (110). The hydraulic pressure supplied to the sliding space portion 110 through the forward movement passage 500 is transmitted to the sliding block 210 located in front of the valve body 214 through the pre- The valve body 214 may be moved forward so as to increase the initial forward movement force of the sliding block 210. In this case, The hydraulic pressure is discharged to the outside of the body 100 through the hydraulic pressure discharge passage 600 on the sliding space portion 110 located in front of the sliding block 210 of the hitting portion 200, 210 can be stably moved forward. Thus, when the sliding block 210 moves forward, the end of the striking rod 220 of the striking part 200 strikes the striking target part 10 of the heat exchanger, Let it out.

As described above, in the striking device for a heat exchanger according to the embodiment, when the striking part 200 is installed on the sliding space part 110 of the body 100 so as to be slidable in the front-rear direction, The hydraulic oil is supplied from the hydraulic inlet passage 300 to the sliding space portion 110 through the rearward movement passage 400 to move the hitting portion 200 rearwardly, The hydraulic pressure of the hitting portion 200 is supplied to the sliding space portion 110 rearward through the forward movement passage 400 to move the hitting portion 200 forward. At this time, when the striking part 200 moves forward, the other end of the striking part 200 strikes the striking part 10 of the heat exchanger, so that stable operation is performed even in a high temperature and dusty environment, Allows my attachment to fall off stably.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Hitting target part 100: Body
110: sliding space part 120: main hydraulic oil path
200: striking part 210: sliding block
211: pressure increasing space part 212: pressure increasing valve
213: spool 214: valve body
215: Postpressing pressure passage 216:
217: front catching jaw 218: rear catching jaw
220: striking rod 300: hydraulic inflow passage
400: backward movement flow passage 500: forward movement flow passage
600: Hydraulic exhaust duct

Claims (5)

A body having a sliding space provided inside thereof and having a main hydraulic fluid path for receiving hydraulic pressure from the outside and discharging the hydraulic fluid;
A striking part having one end slidably inserted in the sliding space part in the forward and backward directions and the other end extending to the outside of the body;
A hydraulic inflow path formed in the body for connecting the main hydraulic fluid path and the sliding space part to allow a part of the hydraulic pressure supplied through the main hydraulic fluid path to flow into the sliding space part;
A rear moving flow path formed at one end of the striking portion to allow the hydraulic pressure supplied from the hydraulic inlet flow path to flow into the sliding space portion positioned at the front end of the striking portion to move the striking portion rearward;
And a hydraulic pressure supply unit that is connected to the hydraulic inflow passage and that supplies the hydraulic pressure supplied from the hydraulic inflow passage to the one end of the hitting unit when the hitting unit is moved backward by the hydraulic pressure supplied to the sliding space unit through the rear- A forward movement flow path for allowing the hitting portion to move backward to the forward position by flowing into the sliding space portion located at the rear side; And
The hydraulic pressure of the inside of the sliding space portion is discharged to the outside of the body while being connected to the backward movement passage or the forward movement passage as it moves forward or backward of the hitting portion And a hydraulic discharge passage for the heat exchanger. The method according to claim 1,
The hitting portion
A sliding block inserted in the sliding space of the body so as to be slidable in the forward and backward directions,
And a striking rod connected to the front end of the sliding block and extending to the outside of the body. The method according to claim 1,
A pressure-increasing space portion connected to the front movement passage and the rear movement passage is provided inside the one end of the hitting portion,
The booster chamber is provided with a booster valve slidably moved in the forward and backward directions,
The pressurizing valve is slidably moved in the forward and backward direction on the pressurizing space part by the hydraulic pressure introduced into the pressurized space part through the forward movement path or the backward movement path, Strike device for heat exchanger to increase power. The method of claim 3,
Wherein the pressure-
A spool having one end coupled to the body and the other end extended to be disposed in the pressure-increased space portion of the striking portion;
And a valve body slidably inserted outside the other end of the spool so as to slide on the pressure-
A rear pressure relieving passage formed in the valve body for introducing the hydraulic pressure supplied from the rearward flow passage into the pressure reducing space portion located in front of the valve body to move the valve body rearward,
Wherein the hydraulic fluid supplied from the forward flow passage is connected to the front flow passage when the valve body is moved backward by the hydraulic pressure supplied to the booster chamber through the after- And a pre-pressurization flow passage for allowing the valve body to move back to the forward position by flowing into the pressure-reducing space portion located at the rear of the valve body. The method of claim 4,
Wherein the hitting portion is formed with a forward engaging jaw portion and a rear engaging jaw portion so as to protrude from the pressure-
Wherein a front end portion of the valve body is engaged when the valve body moves forward and a rear end portion of the valve body is engaged when the rear end portion of the valve body is moved backward.

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