KR900000916Y1 - Sleeve structure of pump with glove - Google Patents

Abstract

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Description

Sleeve structure of pump shaft with ejection groove

1 is a cross-sectional view showing a schematic configuration of a pump provided with a sleeve of the present invention.

2 is an enlarged cross-sectional view showing only the mechanical seal part to show the installation state of the sleeve and the state of taking out the sleeve by using the coupling puller.

* Explanation of symbols for main parts of the drawings

1: pump body 2: pump shaft

3: sleeve 3a: hub

3b: ejection groove 4: spring

5: retainer 6: carbon ring

7: discring 8: wedge

9: mechanical seal part 10: coupling puller

10a, 10b: Between operations 10a ', 10b': Bending end

The present invention relates to the structure of the sleeve used to seal the shaft portion of the pump from liquid, gas, or slurry, etc., in particular, by forming a blowout groove at the end of the sleeve, the sleeve is attached to the pump shaft. It relates to a sleeve structure of the pump shaft provided with a draw groove that can be easily pulled out and reusable in this case.

In general, a pump shaft for rotating or reciprocating a part that acts as a pimp such as an impeller gear or a piston penetrates the main body, and the shaft is sealed from the airtight, watertight or particle with the main body. It must be maintained.

Sealing the shaft from the main body in this way is called a seal, and such a seal type is generally classified into a gland type (cylindrical seal type), a mechanical seal type, and an oil seal type. Among them, the gland method is the most common method, and it is mainly used to keep the sealed state by inserting a fibrous packing. It is used where a small amount of liquid leakage is allowed. The oil seal method is a flexible material such as synthetic rubber or synthetic resin. It is mainly used for oil by sealing using the force of spring, but it is not suitable for high pressure.

The present invention is applied to a method other than the seal method as described above, that is, the mechanical seal method, which handles dangerous liquids, precious liquids, or special liquids, which must be completely prevented from leaking liquids or particles. It is a seal method mainly applied to pumps used in chemical plants.

In the pump using the mechanical seal method, particularly in the case of a pump used for pumping particles, particles frequently flow between the sleeve and the shaft during operation of the pump and the sleeve adheres to the shaft. This is the highest proportion of pump maintenance factors.

In addition, it is very cumbersome and difficult to take out the sleeves stuck on the shaft during the pimp repair work. In the related art, for this purpose, the outer casing of the pump is disassembled to separate the impeller from the shaft, and then the mechanical After separating the inner casing that surrounds a part, the mechanical seal part is separated and dismantled, and then a number of jigs are made to match the size or type of the pump and the sleeve is pulled out. However, this conventional method not only takes too much time for maintenance work, but also because it does not have a lot of free jaws to use the jig on the sleeve itself, it was not easy to take out the work, and also take out the sleeve using a jig If this was impossible, the sleeve had to be heated to take it out, so the sleeve itself is damaged and cannot be reused. Not only is it possible, but if the sleeve sticks badly, there are various problems such as damaging the pump shaft.

The present invention is to solve the above problems with the sleeve of the conventional pump shaft to be easily taken out and at the same time to be reusable after maintenance. According to the type or size of the pump, an annular standardized ejection groove is formed in the hub of the sleeve, and the ejection groove is fitted by inserting a bent end of a coupling puller whose end is bent into a shape. It will be able to do this, described in detail by the accompanying drawings as follows.

1 is a cross-sectional view showing a schematic configuration of a pump provided with a sleeve of the present invention, and FIG. 2 is an enlarged cross-sectional view of only a mechanical seal part to show an installation state of a sleeve and a state of taking out using a coupling puller. As shown in the figures, the tubular sleeve 3 is fitted to one outer peripheral surface of the pump shaft 2 passing through the central portion of the pump body 1, and the outer peripheral surface of the sleeve 3 is connected to the shaft 2. A retainer 5 into which the spring 4 is fitted as a means for crimping and supporting, a carbon ring 6 fastened to the end of the retainer 5, and a disc ring 7 at the end of the spring 4. In the case where the mechanical seal portion 9 composed of the carbon ring 6 and the wedge 8 or the like inclined contact is provided, an annular shape having the same width and depth in the hub 3a of the sleeve 3 is provided. A draw-out groove 3b is formed so that the stage 10a and 10b of the coupling puller 10 can be operated. The bent end portions 10a 'and 10b' formed in the portion can be fitted to each other. 10d is a screw rod and 10e is a handle.

In the above-described configuration, the width and depth of the ejection groove 3b formed on the hub 3a of the sleeve 3 may vary in size according to the size and type of the pump. 2 × 2 (mm), and when the size of the sleeve 3 is large, it was standardized to 1 × 1 (mm) in the case of 3 × 3 (mm) small size.

In the case of taking out the sleeve 3 from the pump shaft 2 using the present invention configured as described above, as shown in FIG. 2, the bent end portions 10a 'and 10b' An operating rod (10a) and a supporting rod (10c) for supporting the same. A screw rod (10d) fitted to the supporting rod (10c). Then, using the coupling puller 10 having a simple structure composed of a handle 10e, the bent ends 10a 'and 10b' of the operation periods 10a and 10b are connected to the hub 3a of the sleeve 3. When the handle 10e is rotated while the end of the screw rod 10d is held in contact with the end of the pump shaft 2 after being inserted into the ejection groove 3b formed in the sleeve 3, the sleeve 3 becomes the pump shaft 2 ) And the coupling puller (1⒧ force acting direction) is coincident so that the sleeve (3) can be easily taken out without damaging the pump shaft (2) or sleeve (3). .

The present invention, such as an ideal ingot, is standardized and formed in the hub (3a) of the sleeve (3), regardless of the size or type of the pump and is formed by the inflow of particles during operation of the pump ( Even if 3) is attached to the pump shaft (2), it can be taken out easily and easily by using the coupling puller (10), and also, as in the prior art, the mechanical seal portion 9 of the pimp is not disassembled one by one. Since it can be taken out without being possible to simplify and time saving of the maintenance industry, as well as damage to the sleeve (3) is not possible to reuse it will also have the effect of cost reduction.

Claims (1)

A tubular sleeve 3 is fitted on one side outer circumferential surface of the pump shaft 2 penetrating the pump body 1, and the outer circumferential surface of the sleeve 3 has a spring therein as a means for pressing and supporting it on the shaft 2. 4 is fitted to the retainer 5 to be fitted, the carbon ring 6 is fastened to the end of the retainer 5, the disc ring 7 interposed at the end of the spring (4) is supported by the carbon ring (6) ) Is provided with a mechanical seal portion 9 composed of a wedge 8 or the like inclined contact, the annular ejection groove 3b is formed in the hub 3a of the sleeve 3 to form a coupling. A sleeve structure of a pump shaft provided with a draw groove, characterized in that the bent end (10a ') (10b') formed at the end of the operation period (10a) (10b) of the puller (10) can be fitted.