CN111412127A - Nuclear-grade reciprocating hydraulic diaphragm pump - Google Patents

Abstract

The invention relates to the field of diaphragm pumps, and particularly discloses a nuclear-grade reciprocating hydraulic diaphragm pump. The hydraulic cylinder comprises a cylinder body and a plunger, wherein a pump inlet and a pump outlet are arranged on the cylinder body, a diaphragm is fixed in the cylinder body, the diaphragm divides an inner cavity of the cylinder body into a hydraulic cavity and a medium cavity, the plunger is in sliding seal with the side wall of the hydraulic cavity, and the pump inlet and the pump outlet are both communicated with the medium cavity; the cylinder body is provided with an exhaust passage which is communicated with the upper end of the hydraulic cavity and can be closed. The nuclear-grade reciprocating hydraulic diaphragm pump can prolong the service life of the nuclear-grade pump and avoid frequent and large-amount leakage of the medium containing radiation.

Description

Nuclear-grade reciprocating hydraulic diaphragm pump

Technical Field

The invention relates to the field of diaphragm pumps, in particular to a nuclear-grade reciprocating hydraulic diaphragm pump.

Background

Nuclear power plant systems include various types of pumps, wherein nuclear-grade pumps are generally used for conveying media containing radiation, small-flow and high-pressure nuclear-grade pumps are basically key devices of the nuclear power plant systems which need to perform safety functions, particularly a filling pump is one of the most key devices of a chemical and volume control (KBA) system, and a plunger type reciprocating pump is generally adopted at present, namely a plunger is in direct contact with the conveying medium of the pump, and the filling material at the position of the plunger is used for sealing the high-pressure media containing radiation.

However, the plunger packing sealing principle determines that the service life is short and leakage exists inevitably, the water containing radiation is leaked and then is generally recycled by adopting a recycling structure and discharged into a sewage system of a nuclear power plant, the leaked water cannot be recycled by adopting a complete sealing structure, and radiation can enter the running environment of a pump to cause negative influence on the environment and increase the sewage treatment difficulty and treatment cost, particularly, the water temperature is about 100 ℃ when the water is pumped and conveyed at a small flow rate, most of the leakage treatment media of the plunger sealing pair are in a steam state, the environment pollution is more serious, and the recycling difficulty is higher. In addition, in a nuclear power station, a pump for injecting high-pressure boric acid also contains easily crystallized boric acid, once the pump stops running or a pump conveying medium stays at a filler sealing part in the running process, the temperature of the medium is reduced to be lower than the crystallization temperature, crystals at the filler part cause great damage to the filler and the plunger when the pump is started, and the service life of the plunger and the filler sealing is rapidly reduced.

When the plunger seals and damages, the medium that contains radiation in the nuclear level pump can take place to leak, and is big to the operating environment pollution, when concentrating the processing to the medium recovery that leaks, handles to contain the radiation medium expense extremely high, and when keeping in repair and retrieving the medium that leaks to the nuclear level pump, the radiation in the medium causes the injury easily to the people, and the cost that will keep apart these radiations is extremely high.

In addition, for the conventional diaphragm pump, a very small amount of gas is inevitably mixed in the liquid under normal pressure, the gas is easy to precipitate when the plunger slides back and forth to increase and decrease the pressure in the hydraulic cavity, and the liquid in the hydraulic cavity is also vaporized to form gas when the pressure in the hydraulic cavity increases and decreases.

Disclosure of Invention

The invention aims to provide a nuclear-grade reciprocating hydraulic diaphragm pump, which is used for prolonging the service life of a nuclear-grade pump, discharging gas precipitated in a hydraulic cavity and avoiding frequent leakage, large amount of leakage and diaphragm rupture of a medium containing radiation.

In order to achieve the purpose, the invention adopts the following technical scheme: a nuclear-grade reciprocating hydraulic diaphragm pump comprises a cylinder body and a plunger, wherein a pump inlet and a pump outlet are formed in the cylinder body, a diaphragm is fixed in the cylinder body and divides an inner cavity of the cylinder body into a hydraulic cavity and a medium cavity, the plunger is in sliding seal with the side wall of the hydraulic cavity, and the pump inlet and the pump outlet are both communicated with the medium cavity; the cylinder body is provided with an exhaust passage which is communicated with the upper end of the hydraulic cavity and can be closed.

The beneficial effect of this scheme does:

1. according to the invention, the medium containing radiation enters the medium cavity from the pump inlet and is then discharged from the pump outlet, and the diaphragm plays a sealing role on the medium cavity, so that the medium cannot enter the hydraulic cavity, and therefore, even if the plunger is damaged in sealing, the medium cannot leak from the damaged part, thereby preventing the radiation in the medium from damaging the environment and human body, and reducing the high cost caused by the medium leakage for recovering the medium.

2. When the pump is used, gas formed by separation and vaporization can be discharged along the exhaust channel, so that damage to the diaphragm caused by overlarge pressure in the hydraulic cavity is avoided, and the service life of the diaphragm is prolonged.

Further, the exhaust channel is communicated with an exhaust groove.

The beneficial effect of this scheme does: because the hydraulic pressure intracavity is full of liquid, so when discharge gas, a small amount of liquid also discharges thereupon, and gas and a small amount of liquid enter the air discharge duct after the hydraulic pressure chamber is discharged in this scheme, and liquid gathers in the air discharge duct bottom under self action of gravity and is collected. The recoverable used repeatedly of liquid in this scheme avoids liquid extravagant.

Further, the hydraulic cavity is communicated with a hydraulic medium collecting tank.

The beneficial effect of this scheme does: liquid is stored in the hydraulic medium collecting tank, after the liquid in the hydraulic cavity is discharged along with gas, the liquid in the hydraulic medium collecting tank can enter the hydraulic cavity, the liquid in the hydraulic cavity is quickly supplemented, and the phenomenon that the diaphragm cannot be driven and a medium is pumped due to too little liquid is avoided.

Further, the exhaust groove is communicated with the hydraulic medium collecting groove.

The beneficial effect of this scheme does: the liquid collected in the exhaust groove can be led into the hydraulic medium collecting groove and directly recycled.

Further, the diaphragm includes membrane portion and annular installation department, the installation department is fixed with membrane portion, and the installation department is located the periphery of membrane portion, the thickness of installation department is greater than the thickness of membrane portion.

The beneficial effect of this scheme does: the thickness of installation department is great, and when the installation, elastic deformation can take place for the installation department, avoids appearing the gap between diaphragm and the cylinder body, leads to the medium infiltration of medium intracavity to the negative pressure intracavity.

Furthermore, one side of the diaphragm, which is close to the medium cavity, is provided with a medium side limiting plate, the medium side limiting plate is fixed with the inner wall of the cylinder body, and a gap for the medium to pass through is arranged between the medium side limiting plate and the side wall of the medium cavity.

The beneficial effect of this scheme does: the medium side limiting plate limits the distance of the diaphragm which swells towards one side close to the medium cavity, the phenomenon that the diaphragm swells towards one side close to the medium cavity to the excessive degree when the plunger slides towards one side close to the medium cavity to enable the pressure in the hydraulic cavity to be excessively increased due to the fact that the pressure in the hydraulic cavity is excessively increased due to the fact that the pressure in.

Further, a plurality of medium through holes are arranged on the medium side limiting plate.

The beneficial effect of this scheme does: in the process of the diaphragm swelling, the size of the space between the diaphragm and the medium side limiting plate is continuously changed, and when the space is increased, the medium in the medium cavity enters the space; when the space reduces, the medium in the space is discharged, and the medium through hole increases the space between diaphragm and the medium side limiting plate and the communicating space of medium chamber for the medium is at the space between diaphragm and the medium side limiting plate and the flow speed between the medium chamber to make the diaphragm can the rapid change.

Furthermore, one side of the diaphragm, which is close to the hydraulic cavity, is provided with a hydraulic side limiting plate, and a gap for liquid to pass through is arranged between the hydraulic side limiting plate and the side wall of the hydraulic cavity.

The beneficial effect of this scheme does: similar with the effect of medium side restriction board, the hydraulic pressure side restriction board in this scheme can restrict the range of waving of diaphragm, avoids the plunger to keeping away from medium chamber one side sliding distance too big, leads to the diaphragm to break.

Furthermore, a plurality of hydraulic medium through holes are arranged on the hydraulic side limiting plate.

The beneficial effect of this scheme does: the hydraulic medium through hole can accelerate the flow speed of the hydraulic medium between the space between the diaphragm and the hydraulic side limiting plate and the hydraulic cavity, so that the diaphragm can be changed rapidly.

Furthermore, a guide channel is arranged at the upper end of the hydraulic side limiting plate, and one end of the guide channel, which is close to the diaphragm, is positioned at the upper end of a space between the diaphragm and the hydraulic side limiting plate.

The beneficial effect of this scheme does: when the hydraulic pressure side limiting plate is used, the hydraulic medium in the space between the diaphragm and the hydraulic pressure side limiting plate can also generate gas, and the gas is easy to accumulate in the space between the diaphragm and the hydraulic pressure side limiting plate.

Drawings

FIG. 1 is a full sectional view of example 1 of the present invention;

fig. 2 is a full sectional view of embodiment 2 of the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the hydraulic pressure cavity comprises a hydraulic pressure cavity 1, a plunger 2, a medium cavity 3, a cylinder body 4, an exhaust valve group 5, an exhaust channel 6, an oil discharge valve group 7, a hydraulic pressure side limiting plate 8, a diaphragm 9, a medium side limiting plate 10, a medium through hole 11, an oil supplementing channel 12, a pump inlet 13, a liquid inlet 14, a cylinder cover 16, a liquid supplementing pipe 17, a valve cover 18, a spring 19, a sealing plate 20, a valve seat 21, a flange 22, an exhaust groove 23 and a guide channel 81.

Example 1

A nuclear-grade reciprocating hydraulic diaphragm pump is shown in figure 1 and comprises a cylinder body 4, a cylinder cover 16 and a plunger 2, wherein a hydraulic cavity 1 with a rightward opening is formed in the cylinder body 4, a medium cavity 3 with a leftward opening is formed in the cylinder cover 16, and a diaphragm 9 is vertically arranged in the cavity. The diaphragm 9 left and right sides is equipped with hydraulic pressure side limiting plate 8 and medium side limiting plate 10 respectively, and diaphragm 9 includes membrane portion and annular installation department, and the membrane portion is located the interior circumference of installation department and membrane portion and installation department integrated into one piece, and the installation department in this embodiment is spherical along the diameter direction of membrane portion, and the diameter of installation department is greater than the width of membrane portion. Hydraulic pressure side limiting plate 8 and medium side limiting plate 10 all are equipped with the mounting groove that aligns with the installation department towards the lateral wall of installation department, and the diameter of mounting groove is less than the diameter of installation department, and during the installation, the installation department is located two mounting grooves. The cylinder block 4 and the cylinder head 16 are fixed by bolts, and the cylinder head 16 presses the hydraulic-side confining plate 8 and the medium-side confining plate 10 against the cylinder block. The diaphragm 9 divides the inner cavity of the cylinder body 4 into a hydraulic cavity 1 on the left side of the diaphragm 9 and a medium cavity 3 on the right side of the diaphragm 9, and a plurality of medium through holes 11 and a plurality of hydraulic medium through holes are respectively arranged on the medium side limiting plate 10 and the hydraulic side limiting plate 8.

The plunger 2 is positioned at the left side of the diaphragm 9, and the right end of the plunger 2 penetrates through the left end of the cylinder 4 and is in sliding seal with the side wall of the hydraulic cavity 1. A hydraulic medium collecting tank is arranged in the cylinder body 4, a U-shaped liquid supplementing pipe 17 is arranged below the cylinder body 4, and the left end and the right end of the liquid supplementing pipe 17 are both glued to the cylinder body 4. The liquid supplementing pipe 17 penetrates through the hydraulic medium collecting tank and is communicated with the bottom of the hydraulic medium collecting tank, and a valve used for sealing the liquid supplementing pipe 17 can be installed on the liquid supplementing pipe 17 in specific implementation. The cylinder body 4 is provided with an oil supplementing channel 12 communicated with the hydraulic cavity 1, and the right end of the liquid supplementing pipe 17 is communicated with the oil supplementing channel 12. The upper end of the cylinder body 4 is provided with an exhaust channel 6 communicated with the top of the hydraulic cavity 1, and the exhaust channel 6 is communicated with an exhaust valve. The exhaust channel 6 is communicated with an exhaust groove 23, and the bottom of the exhaust groove 23 in the embodiment is communicated with the hydraulic medium collecting groove through a pipeline. Along with gaseous exhaust a small amount of hydraulic medium gathering under the action of gravity in this embodiment 23 bottoms in the exhaust groove, flow into the hydraulic medium collecting vat afterwards and be collected, timely recycle hydraulic medium avoids hydraulic medium extravagant.

The upper end and the lower end of the cylinder cover 16 are respectively provided with an outlet and an inlet, the upper end and the lower end of the cylinder cover 16 are respectively provided with a one-way liquid inlet structure and a one-way liquid outlet structure, during specific implementation, the one-way liquid inlet structure and the one-way liquid outlet structure can both adopt one-way valves, the one-way liquid inlet structure and the one-way liquid outlet structure in the embodiment are similar, and the embodiment takes the one-way liquid inlet structure as an.

The lower end of the cylinder cover 16 is provided with a valve cover 18, the valve cover 18 is provided with an opening aligned with the inlet 13, a valve seat 21 is arranged below the valve cover 18, the valve seat 21 is provided with a liquid inlet 14 aligned with the opening, and the one-way liquid inlet structure is positioned between the valve seat 21 and the valve cover 18. One-way liquid inlet structure includes shrouding 20 and elastic component, and shrouding 20 in this embodiment offsets and seals inlet 14 with valve seat 21 upper end, and the elastic component is located shrouding 20 top, and the elastic component in this embodiment adopts spring 19, and the welding is respectively on shrouding 20 and valve gap 18 at spring 19 both ends for make shrouding 20 offset with valve seat 21. A flange 22 is arranged below the valve seat 21, a pump inlet 13 communicated with the liquid inlet 14 is arranged on the flange 22, and the flange 22 is fixed at the lower end of the cylinder cover 16 through bolts and extrudes the valve cover 18 and the valve seat 21 upwards. The one-way liquid outlet structure is different from the one-way liquid inlet structure in that a valve cover 18 above a cylinder cover 16 is positioned on the upper side of a valve seat 21 above the cylinder cover 16, and a sealing plate 20 of the one-way liquid outlet structure is abutted against the upper end of the valve seat 21.

The specific implementation process is as follows:

initially, the hydraulic chamber 1 and the hydraulic medium collecting tank are filled with hydraulic medium, the channel on the flange 22 below the cylinder cover 16 is communicated with a device storing the medium, and the channel on the flange 22 above the cylinder cover 16 is communicated with a device needing to pump the medium. When the pump in the embodiment works, the plunger 2 is driven to slide left and right in a reciprocating manner by adopting structures such as an external hydraulic cylinder, when the plunger 2 slides left, the pressure in the hydraulic cavity 1 is reduced, the diaphragm 9 is blown left, the space in the medium cavity 3 is increased, the pressure is reduced, the sealing plate 20 of the one-way liquid inlet structure slides upwards under the action of the external pressure, and the medium in the medium storage device is sucked into the medium cavity 3 from the pump inlet 13. When the plunger 2 stops sliding leftwards, the pressure in the hydraulic cavity 1 and the medium cavity 3 is unchanged, the closing plate 20 of the one-way liquid inlet structure is reset under the action of the spring 19 and is pressed against the upper end of the valve seat 21 again to close the pump inlet 13.

When the plunger 2 slides rightwards, the pressure in the hydraulic cavity 1 is increased, the diaphragm 9 is driven rightwards, the space in the medium cavity 3 is reduced, the pressure in the medium cavity 3 is increased, and the sealing plate 20 of the one-way liquid inlet structure is abutted against the valve seat 21, so that the sealing plate 20 of the one-way liquid inlet structure cannot continuously slide downwards, namely, the pump inlet 13 cannot be opened, the sealing plate 20 of the one-way liquid outlet structure slides upwards under the high-pressure action in the medium cavity 3, the pump outlet is opened, and the medium in the medium cavity 3 is discharged through the pump outlet. The plunger 2 slides back and forth left and right, and the above steps are repeated, so that the external medium can be sucked into the medium cavity 3 and discharged through the pump outlet.

After the device is used for a period of time, when the diaphragm 9 is blown to the right and the plunger 2 stops moving, the exhaust valve is manually opened, gas in the hydraulic cavity 1 is exhausted from the exhaust valve under the pressure action in the hydraulic cavity 1, and excessive gas is prevented from staying in the hydraulic cavity 1, so that the pressure in the hydraulic cavity 1 is too high, and the diaphragm 9 is broken.

After the plunger 2 slides leftwards and stops moving, a valve on the liquid supplementing pipe 17 is opened, the hydraulic medium collecting tank is communicated with the liquid supplementing pipe 17, the pressure in the hydraulic cavity 1 is reduced due to the fact that the plunger 2 slides leftwards, therefore, when the plunger 2 stops moving, the pressure in the hydraulic cavity 1 is still smaller than the external pressure, and after the valve is opened, the hydraulic medium in the hydraulic medium collecting tank is sucked into the hydraulic cavity 1 to supplement the hydraulic medium in time.

Example 2

On the basis of embodiment 1, as shown in fig. 2, the upper end of the hydraulic side confining plate 8 in this embodiment is provided with a guide channel 81, the guide channel 81 is disposed with a higher left end than a right end, and the right end of the guide channel 81 is located at the upper end of the space between the hydraulic side confining plate 8 and the diaphragm 9, so that the gas in the space between the hydraulic side confining plate 8 and the diaphragm 9 can move from the guide channel 81 into the hydraulic chamber 1 and can be discharged from the gas discharge channel 6, and the gas discharge rate is improved.

The foregoing is merely an example of the present invention and common general knowledge in the art of designing and/or characterizing particular aspects and/or features is not described in any greater detail herein. It should be noted that, for those skilled in the art, without departing from the technical solution of the present invention, several variations and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (10)

1. The utility model provides a reciprocating type hydraulic pressure diaphragm pump of nuclear level, includes cylinder body and plunger, be equipped with pump inlet and pump export on the cylinder body, its characterized in that: a diaphragm is fixed in the cylinder body, the diaphragm divides an inner cavity of the cylinder body into a hydraulic cavity and a medium cavity, the plunger is in sliding seal with the side wall of the hydraulic cavity, and the pump inlet and the pump outlet are both communicated with the medium cavity; and the cylinder body is provided with an exhaust channel which is communicated with the upper end of the hydraulic cavity and can be closed.

2. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 1 wherein: the exhaust channel is communicated with an exhaust groove.

3. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 2 wherein: the hydraulic cavity is communicated with a hydraulic medium collecting tank.

4. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 3 wherein: the exhaust groove is communicated with the hydraulic medium collecting groove.

5. The nuclear grade reciprocating hydraulic diaphragm pump of claim 4 wherein: the diaphragm includes membrane portion and annular installation department, the installation department is fixed with membrane portion, and the installation department is located the periphery of membrane portion, the thickness of installation department is greater than the thickness of membrane portion.

6. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 1 wherein: one side of the diaphragm, which is close to the medium cavity, is provided with a medium side limiting plate, the medium side limiting plate is fixed with the inner wall of the cylinder body, and a gap for the medium to pass through is arranged between the medium side limiting plate and the side wall of the medium cavity.

7. The nuclear grade reciprocating hydraulic diaphragm pump of claim 6 wherein: the medium side limiting plate is provided with a plurality of medium through holes.

8. The nuclear grade reciprocating hydraulic diaphragm pump of claim 6 wherein: one side of the diaphragm, which is close to the hydraulic cavity, is provided with a hydraulic side limiting plate, and a gap for liquid to pass through is arranged between the hydraulic side limiting plate and the side wall of the hydraulic cavity.

9. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 8 wherein: and a plurality of hydraulic medium through holes are formed in the hydraulic side limiting plate.

10. A nuclear grade reciprocating hydraulic diaphragm pump according to claim 8 or 9 wherein: the upper end of the hydraulic side limiting plate is provided with a guide channel, and one end of the guide channel, which is close to the diaphragm, is positioned at the upper end of a space between the diaphragm and the hydraulic side limiting plate.

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