KR100907645B1 - Spurt pump - Google Patents

Abstract

A spurt pump is provided to block the pumping fluid from flowing in between the mechanical seal and the driving shaft by injecting water through a wash water supply line, thereby preventing the noise due to idling and reduction of pumping efficiency. A spurt pump comprises a pump housing in which a casing, a casing cover, an auxiliary casing, and an adapter is combined, a wash water supply line(140) extended to the auxiliary casing from the outside of the pump housing, and a mechanical seal(200) which prevents the leakage of fluid between the pump housing and a drive shaft(130). The mechanical seal is composed of a rotor(210) installed on the drive shaft, an O-ring(230) maintaining airtightness between the mechanical seal and the drive shaft, and a stator(220) which is installed to face the rotor.

Description

Spurt Pump

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sputter pump, and in particular, to improve the structure of a mechanical seal and a structure of a pump housing installed between a rotating shaft rotating at a high speed and a pump housing for rotation of an impeller. The present invention relates to a spurt pump which prevents fluid from leaking out and improves durability of the mechanical seal.

In general, the spurt pump (Spurt pump) is used to transfer the waste, solids, such as manure, waste water using centrifugal force, a cross-sectional view of such a spurt pump is shown in FIG.

Referring to Figure 1 briefly described the structure of the sputter pump as follows.

The spurt pump has a casing 11, a casing cover 12, an auxiliary casing 13, and an adapter 14 coupled to each other to form a pump housing 10, and the casing 11, the casing cover 12, and An impeller 20 is provided inside the pump chamber formed by the coupling of the auxiliary casing 13.

In addition, the drive shaft 30 for rotating the impeller 20 by connecting the impeller 20 and a power source not shown is installed to be connected to the impeller 20 through the adapter 14 and the auxiliary casing 13. A mechanical seal 40 is installed inside the adapter 14 to prevent pumping fluid from leaking between the drive shaft 30 and the auxiliary casing 13.

On the other hand, the adapter 14 is filled with oil for cooling the heat generated from the drive shaft 30 and the mechanical seal 40 during the smooth rotation of the drive shaft 30 and the rotation of the drive shaft (30).

FIG. 2 is a detailed view of portion 'A' of FIG. 1.

The mechanical seal 40 is installed to be fixed to the drive shaft 30 and the rotor 41 to rotate with the drive shaft 30, and the auxiliary casing of the pump housing 10 to face the rotor 41 ( 13 and a spring 43 provided on the rotor 41 to press the rotor 41 to keep the rotor 41 and the stator 42 in close contact with each other. The O-ring 44 is installed on the rotor 41 to maintain an airtight state between the drive shaft 30 and the mechanical seal 40.

The mechanical seal 40 as described above is the rotor 41 while the first sliding surface 41a of the rotor 41 and the second sliding surface 42a of the stator 42 are in close contact with each other to maintain an airtight state. Rotation with the drive shaft 30 prevents the pumping fluid from flowing out between the drive shaft 30 and the auxiliary casing 13.

However, the conventional spur pump as described above has the following problems.

First, the fluid does not penetrate between the first sliding surface 41a and the second sliding surface 42a facing each other during idling of the pump so that friction between the rotor 41 and the stator 42 may be achieved in a dry state. Therefore, there is a problem in that noise is generated by friction between the first sliding surface 41a and the second sliding surface 42a.

In the process of pumping the fluid normally, the pumped fluid flows between the stator 42 and the drive shaft 30, and the pumped fluid is again supplied by the first sliding surface 41a and the second sliding surface by centrifugal force. It penetrates between 42a) and acts as a lubricant between the 1st sliding surface 41a and the 2nd sliding surface 42a. However, when the pump is idle, since there is no fluid that penetrates between the first sliding surface 41a and the second sliding surface 42a, the first sliding surface 42a and the second sliding surface 42a are rubbed in a dry state, so noise Along with this, there is a problem that causes damage to the mechanical seal 40.

Second, because the pumping fluid contained in the various foreign matters are introduced between the stator 42 and the drive shaft 30 and between the stator 42 and the auxiliary casing 13, the rotation of the drive shaft 30 is made of a mechanical seal ( 40) is easily damaged, and thus there is a problem that frequent replacement of the mechanical seal 40 is required.

The present invention has been made in consideration of the above problems, and an object of the present invention is to improve the structure of the mechanical seal so that noise does not occur even when the pump is idle, and can immediately discharge the fluid introduced with the contaminants. By providing a sputter pump that can prevent the mechanical seal from being damaged.

The spurt pump of the present invention, which achieves the above object and performs a problem for eliminating the drawbacks of the related art, has a pump housing in which a casing, a casing cover, an auxiliary casing, and an adapter are coupled to each other, and is installed in the pump housing. A sputter pump having an impeller for delivering fluid, a drive shaft installed through a pump housing so as to connect the impeller and a power source, and a mechanical seal for preventing fluid from leaking between the drive shaft and the pump housing. The rotor of the mechanical seal is installed on the drive shaft to rotate together with the drive shaft at a position close to the impeller with an O-ring for maintaining airtightness between the drive shaft and the mechanical seal, wherein the stator of the mechanical seal is located farther than the rotor from the impeller. While facing the rotor The mechanical seal is configured to be supported by the lock auxiliary casing to allow the O-ring to prevent pumping fluid from entering the inner region of the stator while allowing the oil filled in the adapter to flow into the inner region of the stator. The washing water supply line for supplying water for washing the pumping fluid flowing into the outside of the curl seal is installed to extend from the outside of the pump housing to the auxiliary casing, characterized in that configured to spray water to the outside of the mechanical seal.

On the other hand, the rotor is in contact with the stator contact block having a first sliding surface to maintain the airtight state; A plurality of springs pressurized to maintain the contact block in contact with the stator; The spring and the O-ring is fixed to the drive shaft while being installed, coupled to the contact block with the spring interposed therebetween, so that the space that accommodates the spring and a portion of the contact block in contact with the spring so as not to be exposed to the outside It is characterized in that consisting of; support blocks provided therein.

In addition, the fixing groove is formed in the rotor to provide a space for the O-ring is installed, the O-ring installed in a wider width than the thickness of the O-ring in the longitudinal direction of the drive shaft to form a space capable of flow in the longitudinal direction of the drive shaft; And a backup ring installed to move in the longitudinal direction of the driving shaft together with the O-ring in the fixing groove, to prevent deformation of the O-ring.

According to the present invention having the characteristics as described above, the pumping fluid containing various foreign matters do not flow between the mechanical seal and the drive shaft, and withdrawal again with the washing water from the outside of the mechanical seal to reduce the damage of the mechanical seal It became possible.

In addition, the oil filled in the adapter flows into the mechanical seal, and the introduced oil flows naturally between the sliding surface of the rotor and the stator to prevent the sliding surface of the sliding surface and noise even when the pump is idle. I can do it.

In addition, the backing ring prevents the O-ring holding the airtight state between the mechanical seal and the drive shaft from being driven between the drive shafts, thereby preventing the pump efficiency from being lowered due to the O-ring damage.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

3 shows a cross-sectional view of a stud pump according to a preferred embodiment of the present invention.

In the stud pump of the present invention, an impeller 120 which is connected to a power source not shown by the drive shaft 130 and rotates is installed inside the pump housing 110 to send a fluid by rotation of the impeller 120. The configuration is the same as that of a conventional spurt pump.

However, the stud pump of the present invention improves the structure of the mechanical seal 200 and the structure of the pump housing 110, thereby minimizing damage to the mechanical seal 200, and the mechanical seal 200 when idling the pump. The noise generated by the friction between the rotor 210 and the stator 220 will be generated.

Meanwhile, the pump housing 110 includes a casing 111, a casing cover 112, an auxiliary casing 113, and an adapter 114. Here, the casing 111 is provided with a suction port 111a through which the fluid is sucked to form one wall of the pump housing 110, and the casing cover 112 is provided with a discharge port 112a through which the fluid is discharged. In addition, it is combined with the casing 111 to form the side wall of the pump housing 110, the auxiliary casing 113 is combined with the casing cover 112 to form the other wall of the pump housing 110 The drive shaft 130 connected to the power source is to provide a space connected to the impeller 120. In addition, the adapter 114 is installed in the auxiliary casing 113, the frictional heat generated when the rotation along with the environment in which the mechanical seal 200 or the drive shaft 130 rotates smoothly when the drive shaft 130 is rotated. It provides a space filled with oil for cooling the.

Figure 4 is a detailed view of the 'B' portion of Figure 3, Figure 5 shows a cross-sectional view of the mechanical seal according to the present invention.

The mechanical seal 200 is a basic configuration consisting of a rotor 210 and the stator 220 is similar to the conventional mechanical seal, the mechanical seal 200 of the present invention, the rotor 210 is a stator ( Compared to 220, it is installed closer to the impeller 120 to block the pumping fluid from flowing into the inner region I of the stator, while the oil filled inside the adapter 114 flows into the inner region I. To allow.

To this end, the rotor 210 is installed to be fixed to the drive shaft 130 to be located at a distance closer to the impeller 120 than the stator 220, and the mechanical seal 200 and the inside of the rotor 210 O-ring 230 is provided for maintaining the airtight between the drive shaft 130.

In addition, the stator 220 is supported by the auxiliary casing 113 so that the second sliding surface 220a provided at one side thereof faces the first sliding surface 210a provided at the rotor 210. . Of course, the stator 220 is installed to maintain the remote with the impeller 120 compared to the rotor 210 as described above.

Meanwhile, in order to support the stator 220 which is installed at a distance from the impeller 120 as compared to the rotor 210, the auxiliary casing 113 protrudes toward the inside of the adapter 114. ) Is provided.

When the mechanical seal 200 is configured as described above, the O-ring 230 disposed between the rotor 210 and the drive shaft 130 is introduced into the inner region I of the stator 220. To prevent it. Meanwhile, the oil filled in the adapter 114 flows into the inner region I of the stator 220, and the oil introduced into the inner region I of the stator 220 is formed by the centrifugal force of the rotating drive shaft 130. 1 soaking between the sliding surface (210a) and the second sliding surface (220a) to form a lubrication film between the first sliding surface (210a) and the second sliding surface (220a) to prevent the noise is generated during the idling of the pump Done.

Meanwhile, in order to prevent damage to the rotor 210 which is exposed to the pumping fluid introduced between the impeller 120 and the auxiliary casing 113 as it is, the washing water supply line 140 supplying the washing water to the adapter 114 is provided. It is provided. The wash water supply line 140 supplies the wash water from the outside of the adapter 114 to the outside of the mechanical seal 200 through the protruding support 113a of the adapter casing 113 and the inside of the adapter 114. Is installed. Of course, the washing water supply line 140 is connected to a separate pump (not shown) to receive water, and when the pump is operated, water is sprayed to the outside of the mechanical seal 200.

As described above, in the washing water sprayed from the washing water supply line 140, various foreign substances in the pumping fluid introduced between the impeller 120 and the auxiliary casing 113 are not fixed to the mechanical seal 200, and the driving shaft 130 is impeller. By assisting to be discharged again by the centrifugal force of the 120, damage to the rotor 210 generated by rotating the rotor 210 in a state where foreign matter is caught between the auxiliary casing 113 and the rotor 210. Can be prevented.

Meanwhile, a pumping fluid introduced between the impeller 120 and the auxiliary casing 113 is provided with a plurality of springs 240 installed on the rotor 210 to provide a force for bringing the rotor 210 and the stator 220 into close contact with each other. In order to prevent the damage of the spring 240 generated by rotating in the exposed state as it is in the rotor 210 is made of the following structure.

The rotor 210 has a first sliding surface 210a and is in contact with the stator 220 and keeps in contact with the contact block 211, and the contact block 211 is connected to the stator 220. A plurality of springs 240 for pressing the contact block 211 to maintain the contact state, the spring 240 and the O-ring 230 is supported while being fixed to the drive shaft 130 and the spring 240 The space 213 is coupled to the contact block 211 with the space between the spring 240 and the contact block 211 in contact with the spring 240 so that the spring 240 is not exposed to the outside. It is composed of a support block 212 provided therein.

Meanwhile, the space 213 is provided by forming a groove having a circular cross section on one side of the support block 212 so that the contact block 211 can be inserted therein, and the spring 240 is formed inside the space 213 formed as described above. In addition, at least one fixing pin 214 for coupling the contact block 211 and the support block 212 is installed, and the contact block 211 is inserted into the space 213 to be coupled to the fixing pin 214. As a result, the contact block 211 and the support block 212 are coupled to each other, and the space 213 is closed by the combination of the contact block 211 and the support block 212, so that the spring 240 is pumped by the fluid. This can prevent damage.

FIG. 6 is a detailed view of part 'C' of FIG. 5.

O-ring of the conventional mechanical seal is frequently installed to be fixed to the inner side of the rotor, the curling between the drive shaft and the rotor during rotation of the drive shaft has been frequently occurred. The rotor 210 of the present invention provides a space in which the O-ring 230 is installed, but the installed O-ring 230 forms a space in which a flow is possible within a predetermined range in the longitudinal direction of the drive shaft 130. A fixing groove 215 having a wider width than the thickness of the O-ring 230 is formed in the longitudinal direction of the), and is installed in the fixing groove 215 together with the O-ring 230 and the driving shaft together with the O-ring 230. The backup ring 231 is provided to move in the longitudinal direction of the 130 and prevent the O-ring 230 from being rolled between the drive shaft 130 and the rotor 210.

In the sputter pump of the present invention configured as described above, when the rotation of the drive shaft 130 is started for the delivery of the fluid, the washing water is supplied through the washing water supply line 140 at the same time, and the washing water supplied in this way is operated during the operation of the pump. In addition to preventing various foreign substances contained in the pumping fluid introduced between the impeller 120 and the auxiliary casing 113 from being fixed to the outside of the rotor 210, the pumping flow is improved by improving the fluidity of the pumped fluid introduced. It will promote the discharge of the fluid.

Meanwhile, oil of the adapter 114 is introduced into the inner region I of the stator 220 while the driving shaft 130 is rotated for the rotation of the impeller 120 to lubricate between the driving shaft 130 and the stator 220. In addition, it is possible to prevent the damage or noise of the mechanical seal 200 by forming a lubricating film by flowing between the first sliding surface 210a and the second sliding surface 220a.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a cross-sectional view of a conventional spur pump,

2 is a detailed view of portion 'A' of FIG. 1;

3 is a cross-sectional view of a stud pump according to a preferred embodiment of the present invention,

4 is a detailed view 'B' of FIG.

5 is a cross-sectional view of the mechanical seal according to the present invention,

FIG. 6 is a detailed view of part 'C' of FIG. 5;

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

110: pump housing 111: casing

112: casing cover 113: auxiliary casing

114: adapter 120: impeller

(130): drive shaft 140: washing water supply line

(200): mechanical seal (210): rotor

210a: first sliding surface 211: contact block

(212): support block (213): space

(215): fixing groove 220: stator

230: O-ring 231: backup ring

240: spring

Claims (3)

A casing 111, a casing cover 112, an auxiliary casing 113, and an adapter 114 are coupled to each other, and an impeller installed in the pump housing 110 to discharge fluid. 120, a drive shaft 130 installed through the pump housing 110 to connect the impeller 120 and a power source, and a US to prevent fluid from leaking between the drive shaft 130 and the pump housing 110. In the spurt pump having a mechanical seal 200, The rotor 210 of the mechanical seal 200 has the O-ring 230 for maintaining the airtightness between the drive shaft 130 and the mechanical seal 200, the drive shaft 130 in a position close to the impeller 120 Installed in the drive shaft 130 to rotate together with the stator 220 of the mechanical seal 200 facing the rotor 210 while being located at a distance from the impeller 120 than the rotor 210. The oil filled in the adapter 114 is stator 220 while the O-ring 230 blocks the pumping fluid from entering the inner region I of the stator 220 so as to be supported by the auxiliary casing 113. Mechanical seal 200 is configured to allow the flow into the inner region (I) of the, Washing water supply line 140 for supplying water for washing the pumping fluid flowing into the mechanical seal 200 is installed to extend from the outside of the pump housing 110 to the auxiliary casing 113, the mechanical seal Spurt pump, characterized in that configured to spray water out of (200). The method of claim 1, wherein the rotor 210, A contact block 211 having a first sliding surface 210a which is in contact with the stator 220 and maintains an airtight state; A plurality of springs 240 for pressing the contact block 211 to maintain contact with the stator 220; The spring 240 and the O-ring 230 are fixed to the drive shaft 130 while being supported and coupled with the contact block 211 with the spring 240 therebetween, the spring 240 being external Spur pump, characterized in that consisting of a support block (212) provided therein a space (213) for receiving a portion of the spring 240 and the contact block (211) in contact with the spring 240 so as not to be exposed to. The method according to claim 1 or 2, Is formed in the rotor 210 to provide a space for the O-ring 230 is installed, the installed O-ring 230 in the longitudinal direction of the drive shaft 130 to form a space that can flow in the longitudinal direction of the drive shaft 130 Fixing groove 215 formed in the rotor 210 to have a wider width than the thickness of the O-ring 230; And a backup ring 231 installed to move in the longitudinal direction of the driving shaft 130 together with the O-ring 230 in the fixing groove 215 to prevent deformation of the O-ring 230. Spurt pump.

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