SU1190086A1 - Centrifugal pump for transferring corrosive liquid - Google Patents

Abstract

1. CENTRIFUGAL PUMP FOR TRANSFER OF AGGRESSIVE LIQUIDS KOS1TEI, comprising a housing, a shaft with a seal, an impeller mounted in the housing with a hub mounted on the shaft by means of a key, cheeks with screws and a protective cap with a thread opposite to the direction of rotation of the wheel, while the flow-through part of the pump and the protective cap is made of a material resistant in aggressive media, and the shaft seal is made in the form of an omentum, tightened by means of a pressure sleeve, characterized in that, in order to increase the service life of us wasp by enhancing the reliability of the impeller fastening on the shaft and preventing the penetration of corrosive fluid to parts of the pump, the protective cap provided with blades, and the shaft - with an end seal with an additional pressure sleeve and a movable sealing sleeve with a collar, while a seal is installed opposite the collar on the hub a gasket and, on the shaft and sealing sleeve, a running thread is made opposite to the direction of rotation of the shaft, the sealing sleeve is screwed onto the shaft, the oil seal is located between the latter and the body, and the housing is made water seal chamber communicating with a fluid source and nonaggressive densified end gland, the cheeks are designed as polygons. (L 2. Pump according to claim 1, characterized in that the sealing sleeve is made of fluoroplastic, graphitized fluoroplastic or pyrographite; about 00 a

Description

The invention relates to pump engineering, namely, to designs of centrifugal pumps for pumping corrosive and corrosive fluids.

The purpose of the invention is to increase the service life of the pump by increasing the reliability of mounting the impeller on the shaft and preventing the penetration of corrosive liquid to pump parts that are not corrosion resistant.

FIG. 1 shows the construction of a pump; in fig. 2 shows the cheeks for fastening the pump impeller to the shaft.

The centrifugal pump for pumping corrosive liquids comprises a housing 1, a shaft 2 with a seal 3, an impeller 4 mounted in the housing 1 with a hub 5, mounted on the shaft 2 by means of a key 6, cheeks 7 and 8 with screws 9 and a protective cap 10 with a thread 11, opposite to the direction of rotation of the wheel 4. The flow part of the pump and the protective cap 10 are made of a material resistant in aggressive media. The seal 3 of the shaft 2 is made in the form of the gland 12, which is tightened by means of the pushing sleeve 13. The protective cap 10 is equipped with blades 14, and the shaft 2 - with the end packing 15 with the additional pushing sleeve 16 and the movable sealing sleeve 17 with the shoulder 18. Opposite of the shoulder 18 A sealing gasket 19 is installed on the hub 5. A shaft 20 is made on the shaft 2 and the sealing sleeve 17 opposite to the direction of rotation of the shaft 2. The sealing sleeve 17 is screwed onto the shaft 2 along the driving thread 20. The oil seal 12 is located between the sealing sleeve 17 and the housing 1. In the last is made of the camera 21 of the seal, communicated with a source of non-aggressive fluid (not shown) through the fitting 22.

The chamber 21 is sealed with an end seal 15. The cheeks 7 and 8 are made in the form of many squares (Fig. 2). The flow part of the pump is made with a fluoroplastic coating 23, and the impeller 4 is entirely made of fluoroplastic. The protective cap 10 and the sealing sleeve 17 are made of fluoroplastic, graphitized fluoroplastic or pyrographite.

The end seal 15 is enclosed in an annular cooling chamber 24 inlet by a choke 25 with a source (not shown) of a coolant, such as water.

The pump works as follows.

When the shaft 2 rotates from a drive (not shown), the torque is transmitted to the impeller through a key 6 and cheeks 7 and 8, made in the form of polygons (Fig. 2) and relieved by screws 9. Due to the fact that cheeks 7 and 8 are made in the form of many squares, the surface of their contact with the fluoroplastic impeller 4 increases significantly. As a result, the contact pressure of the cm decreases, which increases the reliability of the impeller 4 fastening on the shaft 2. When the impeller 4 rotates, the liquid under increased pressure is supplied to the discharge nozzle. The protective cap 10 with the blades 14 under the action of the moment of resistance acting on the blades is screwed onto the shaft,

 providing a constant contact through the gasket to the hub 5 of the wheel 4. This thereby prevents the cap 10 from being unscrewed and the penetration of corrosive liquid to the un-coated, resistant parts of the pump

 to aggressive fluid, namely to the shaft 2, cheeks 7 and 8, screws 9 and key 6.

On the opposite side of the impeller 4, there is a movable sealing sleeve 17 under the action of a moment of frictional force that occurs when the sleeve 17 rotates between

0 its surface and the gland 12, moves along the running thread 20 in the axial direction to the impeller 4 until the collar 18 contacts the sealing gasket 19 on the hub 5 of the wheel 4. The sleeve 17 moves in the axial direction until the moment of force The friction between the sleeve 17 and the stuffing box 12 is not balanced by the moment of resistance in the running thread 20. Due to the described mechanism of the sealing action,

Q is a self-sealing of the contact surfaces of the collar 18 of the sleeve 17 and the gasket 19 and the penetration of corrosive fluid from the pump cavity to the shaft 2 is prevented. The seal between the housing 1 and the sleeve 17 is sealed by the gland 12 as well as by the hydraulic seal chamber 21.

Liquid (e.g. distilled water) is supplied from a special source, such as a pressure tank (not shown), to chamber 21 under such pressure so as to allow it to pass through the gland.

0 12 into the cavity of the pump. This ensures reliable sealing of the pump cavity. In addition, for certain technological processes, the required amount of distilled water required for chemical synthesis in the production of hydrofluoric acid is supplied to the pump cavity. End seal 15 provides sealing chamber 21 trap. The gland 15 is cooled by pumping technical

0 water through the annular chamber 24. The density of stuffing of the glands 12 and 15 is required.

When the pump is stopped, the aggressive fluid is drained from it and its cavities are washed with distilled water.

Fi.2.

Claims (2)

1. CENTRIFUGAL PUMP FOR TRANSMISSION OF AN AGGRESSIVE BONE FLUID, comprising a housing, a shaft with a seal, an impeller installed in the housing with a hub, mounted on the shaft by means of dowels, cheeks with screws and a protective cap with a thread opposite to the direction of rotation of the wheel, while the flow part of the pump and the protective cap are made made of a material that is resistant in aggressive environments, and the shaft seal is made in the form of an oil seal, tightened by means of a pressure sleeve, characterized in that, in order to increase the service life of the pump by increasing the reliability ty fastening of the impeller on the shaft and preventing the penetration of aggressive fluid to the pump parts, the protective cap is equipped with blades, and the shaft is equipped with an end gland with an additional pressure sleeve and a movable sealing sleeve with a collar, while a sealing gasket is installed on the hub opposite the collar, and the sealing sleeve has a running thread opposite to the direction of rotation of the shaft, the sealing sleeve is screwed onto the shaft, the stuffing box is located between the latter and the housing, and a hydroz chamber is made in the housing of the creature communicated with a source of non-aggressive liquid and sealed with an end gland, and the cheeks are made in the form of polygons. 2. The pump according to π. 1, characterized in that the sealing sleeve is made of fluoroplastic, graphitized fluoroplastic or pyrographite. 8006 P HS IN