KR100291161B1 - Diaphragm pump - Google Patents

Abstract

According to the present invention, a diaphragm pump having a simple structure that can effectively prevent pulsation of a discharged fluid is disclosed. A diaphragm is installed in the opening of the first pump chamber, and a cylindrical diaphragm having an opening is formed in the lower portion of the second pump chamber. During the pumping operation, the air inside the second pump chamber is connected to the outside of the cylindrical diaphragm 21. It is stored in a compressed state inside the cylindrical bulkhead by the fluid being pushed through to form a pressure equalizing chamber, which effectively prevents pulsation of the discharged fluid, thereby preventing breakage of the piping system in advance and significantly reducing noise. have.

Description

Diaphragm pump

The present invention relates to a diaphragm pump, and more particularly, a diaphragm which effectively prevents a pulsation phenomenon of a discharged fluid by providing a first pump chamber in which a diaphragm is installed and a second pump chamber in which a cylindrical diaphragm having a lower opening is arranged. It is about a pump.

Diaphragm pump is a device that pumps fluid by converting motor rotational motion into linear reciprocating motion of diaphragm through a mechanism such as a cam.It is generally used for metering of liquid chemicals or drugs because the discharge flow rate is small. have.

1 is a schematic view for explaining an example of a conventional diaphragm pump, the diaphragm 110 is pressed into the support ring 120 in the opening of the pump head 100 to form a pump chamber 130, The suction hole 105 and the discharge hole 106 are formed in the lower and upper portions of the body 102.

The suction hole 105 and the discharge hole 106 are opened or closed by the check ball 140, respectively, and the suction hole 105 and the discharge side connector 160 end of the pump head 100 are illustrated in FIG. 1. An open valve seat 141 having a cross groove shape as shown in (C) is formed, and at the discharge end 106 and the suction side connector 150 end of the pump head 100 are tapered. The closing valve seat 142 is formed.

Referring to the operation of the conventional general diaphragm pump configured as described above is as follows.

When a motor (not shown) is driven to drive the pump, the rotational motion of the motor is changed to a reciprocating motion of the diaphragm shaft 111 by a mechanism such as an eccentric cam, so that the diaphragm 110 operates forward and backward. FIG. 1A shows a state in which the diaphragm is in reverse operation, that is, a suction stroke, and FIG. 1B shows a state in which the diaphragm is in forward operation, that is, a discharge stroke.

During the suction stroke, both the suction side and the discharge side check balls 140 move toward the center of the pump head 100 due to the negative pressure in the pump chamber, and the suction side 105 of the pump head 100 is open to the suction end. The valve seat 141 is formed so that the fluid is sucked into the pump chamber 130 along the cross groove, the discharge hole 106 is closed by the check ball. In the following discharge stroke, all of the check balls 140 move outward of the pump head 100, so that the suction hole 105 is closed and only the discharge hole 106 is opened so that the fluid in the pump chamber is discharged to the connector 160. It is discharged to the outside along the cross groove formed in the.

However, the conventional diaphragm pump as described above has the advantage that the average discharge amount is almost constant when viewed for a long time, but because the pumping action is divided into the suction stroke and the discharge stroke is made intermittently, as shown in Figure 1D Similarly, there was a fundamental problem that pulsation occurred in the discharged flow rate.

In order to prevent the pulsation of the discharge flow rate, conventionally by connecting two or more pumps in parallel to reduce the pulsation by changing the stroke (see Fig. 1E), as shown in Figure 2 in the middle of the fluid Since the air chamber 200 is installed and the air in the air chamber 200 is compressed during the discharge stroke, the discharge amount toward the discharge pipe 210 is reduced, and the air chamber during the discharge stroke is reduced by the expansion force of the compressed air during the suction stroke. A method of discharging the fluid stored in the 200 to the discharge pipe 210 side was used. Reference numeral 220 denotes a safety valve to open when the pressure of the fluid exceeds a predetermined value, so that the high pressure fluid is recovered through the return pipe 230, and 201 denotes a pressure gauge.

However, the method of connecting two or more pumps in parallel has a problem in that the installation cost is sharply increased compared to the effect, and in the case of installing the air chamber in the middle of the fluid line, the installation work is not easy and the connector of the pump And when the fluid line is a tube type, installation was difficult.

In addition, the connection part is often broken by vibration of the air chamber during pump operation, and water hammering due to pulsation occurs because the pulsation of the discharge flow rate itself from the pump is not fundamentally removed. Therefore, there was a risk of damage to the piping or the like during overpressure.

Accordingly, an object of the present invention is to provide a diaphragm pump having a simple structure that can effectively prevent the pulsation phenomenon of the discharged fluid.

1A and 1B are principal part sectional views for explaining the structure and operation of the conventional diaphragm pump.

1C is a plan view of an open valve seat in the shape of a cross groove.

1D and 1E are graphs for explaining the pulsation phenomenon occurring in the discharged flow rate, respectively, and a graph showing the form of the discharged flow rate when the pulsation phenomenon is reduced.

2 is a view showing an example in which an air chamber and a safety valve are installed in the middle of a conventional fluid pipe.

Figure 3 is a longitudinal sectional view of the diaphragm pump in accordance with an embodiment of the present invention.

4 is a cross-sectional view taken along the line A-A of FIG.

5 is an exploded perspective view of a diaphragm pump according to an embodiment of the present invention.

6 is a detailed view of a discharge side valve body.

7 is a longitudinal sectional view showing another embodiment of the present invention.

8 is a longitudinal sectional view showing yet another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

11: cylindrical body 12: dividing wall

13: 1st pump room 14: 2nd pump room

15: cover plate 16: inlet

17: discharge path 18: discharge port

23: equalization chamber 42: discharge side valve body

A diaphragm pump according to the present invention for achieving the above object comprises: a diaphragm pump in which fluid is intermittently discharged by a forward and backward operation of a diaphragm, the body comprising a cylindrical body; A partition wall partitioning the inside of the cylindrical body into a first pump chamber and a second pump chamber; A diaphragm disposed in the opening of the first pump chamber; Driving means for operating the diaphragm forward and backward; A cover plate coupled to the opening of the second pump chamber; A cylindrical diaphragm which is formed in a cylindrical shape with a lower portion opened and is formed inside the second pump chamber to form a pressure equalizing chamber in which compressed air is received; A suction port formed in said first pump chamber; Suction valve means for opening and closing the suction port; A discharge passage communicating the first pump chamber with the second pump chamber; Discharge valve means for opening and closing the first discharge path; And a discharge port formed in the second pump chamber.

Preferably, the discharge valve means, the cylindrical valve body having one side is opened, the other side is formed with a projection and a plurality of through holes formed around the projection; A ball movably disposed within the valve body; And a valve seat disposed in the opening of the valve body, wherein the dividing wall is provided with a valve installation hole communicating with the discharge passage, and the discharge valve means is disposed in the valve installation hole, and an upper portion of the valve installation hole. The projection of the valve body is pushed downward by the lower surface of the cap coupled to the, so that the space around the projection in the valve installation hole forms a part of the discharge passage.

In addition, preferably, the cover plate is provided with a pressure adjusting hole and a high pressure fluid recovery hole, the valve plate which is elastically supported by a spring is installed outside the pressure adjusting hole and the high pressure fluid recovery hole, the second pump chamber When the pressure is greater than or equal to a predetermined value, the spring is compressed so that the high pressure fluid in the second pump chamber is discharged through the pressure adjusting hole and the overpressure fluid recovery hole.

The features and expected advantages of the present invention will become more apparent from the following detailed description and the preferred embodiments.

3 to 6 is a view for explaining the configuration and operation of the diaphragm pump according to an embodiment of the present invention, Figure 3 is a longitudinal cross-sectional view, Figure 4 is a cross-sectional view of the cylindrical AA line of Figure 3 the lower opening. Fig. 5 shows an exploded perspective view, and Fig. 5 shows a partially cutaway perspective view of the discharge side valve sea.

In the following description, matters that are not important in understanding the present invention with the same configuration as the prior art will be omitted.

The cylindrical body 11 is divided left and right by the dividing wall 12 to form the first pump chamber 13 and the second pump chamber 14.

The diaphragm 110 is pressed into the opening of the first pump chamber by the support ring 120, and the cover plate 15 is coupled to the opening of the second pump chamber 14 via the gasket 75. A cylindrical diaphragm 21 having an opening 22 formed in the lower portion of the pump chamber 14 is installed. In the pumping operation, air that is pushed through the outside of the cylindrical diaphragm 21 during the pumping operation is provided. It is stored in a compressed state inside the cylindrical partition wall 21 to form a pressure equalizing chamber (23).

A suction port 16 is formed at a lower portion of the first pump chamber 13, and a suction side valve body 32, a suction side check ball 33, and a suction side connector 31 coupled to the suction port 16. A suction valve means 30 composed of the suction side valve seat 34 is disposed, and a discharge port 18 is formed in the upper portion of the second pump chamber 14 to which the discharge side connector 51 is coupled.

On the other hand, in the dividing wall 12, a discharge passage 17 for communicating the first pump chamber 13 and the second pump chamber 14 is formed, and a discharge valve mounting hole 45 is formed in the middle of the discharge passage 17. do. A discharge valve means 40 composed of a discharge side valve body 42, a discharge side check ball 43, and a discharge side valve seat 44 is disposed in the discharge valve mounting hole 45, and the discharge side valve body 42 is disposed. The ball guide hole 42c and the through hole 42b are formed in the same manner as the suction side valve body 32, but the protrusion 42a is formed at the upper portion thereof, so that the cap is formed in the opening of the discharge valve mounting hole 45. When the 41 is engaged, the projection 42a is pressed by the lower surface of the cap 41 so that the discharge side valve body 42 is securely fixed in the discharge valve mounting hole 45, and the periphery of the projection 42a is fixed. The space of the portion forms part of the discharge path 17.

By constructing the discharge valve means 40 in accordance with the present invention, it is more reliably operated than in the conventional valve means shown in Fig. 1C, chattering is prevented and the durability of the valve seat portion is increased.

In the drawings, reference numeral 61 denotes a drain pipe, 62 denotes a drain valve, 71 to 74 a packing for preventing the leakage of air and fluid, and 76 denotes a cover plate, a cylindrical body, and a bolt for coupling the support ring, respectively.

Referring to the operation and operation of the diaphragm pump configured as in the embodiment as follows.

The equalization chamber 23 in an operating state is in a state as shown in FIG. That is, the space between the cylindrical diaphragm 21 and the cylindrical body 22 and the lower portion of the cylindrical diaphragm 23 is filled with the fluid to be pumped, and the upper space inside the diaphragm, that is, the equalization chamber 23, is filled with compressed air. When the air is filled in the equalization chamber 23 is completely blocked from the outside by the gasket 75 and the fluid at the bottom to maintain a certain amount of air at all times.

3 shows a state in which the diaphragm 110 is advanced, that is, a discharge stroke, in which the discharge side check ball 15 is separated from the discharge side valve seat 44 and moved upward. Accordingly, the discharge passage 17 is opened and at the same time, the fluid introduced into the first pump chamber 13 during the previous suction stroke is discharged into the second pump chamber 14 through the discharge passage 17. As a result, the pressure of the fluid in the second pump chamber 14 increases, so that the air in the equalization chamber 23 is further compressed, and the level of the fluid in the cylindrical diaphragm 21 increases. That is, not all of the fluid flowing into the second pump chamber 20 through the discharge passage 17 is discharged through the discharge discharge port 18, but some of the fluid level rises in the diaphragm 21. Since it contributes to the pressure increase of the air, sudden fluctuations in the discharge flow rate are prevented.

In the subsequent intake stroke, the torches valve means 40 is closed to prevent the fluid inside the second pump chamber 14 from flowing back to the first pump chamber and from the first pump chamber 13 to the second pump chamber 14. Fluid discharge is stopped. However, the fluid in the second pump chamber 14 is continuously discharged through the discharge port 18 and the discharge-side connector 51 by the air pressure in the pressure equalizing chamber 23 that was compressed during the previous discharge stroke, and at the same time the cylindrical diaphragm 21 The level of fluid inside is gradually decreased. Therefore, even during the suction stroke, the discharge flow rate discharged from the second pump chamber is not drastically reduced but becomes almost equal to that of the discharge stroke of the first pump chamber.

7 is a cross-sectional view showing another embodiment of the present invention. Referring to Figure 7,

A pressure adjusting hole 81 and a high pressure fluid recovery hole 82 are formed in the cover plate 15 coupled to the opening of the second pump chamber 14, and the pressure adjusting hole 81 and the high pressure fluid recovery hole 82 are formed. The valve plate 83 which is elastically supported by the spring 85 is provided in the outer side. The valve plate 83 is preferably formed of an elastic material. The spring 85 is disposed inside the spring casing 84 screwed to one side of the cover plate 15, and a push plate 86 is disposed between the spring 85 and the valve plate 83. Allow the valve plate to operate smoothly. One end of the spring casing 84, the cap 88 is screwed to adjust the elastic force of the spring 85, a spring seat 87 is disposed between the cap 88 and the spring 85 is the spring seat 87 .

By such a configuration, when the pressure in the second pump chamber is equal to or greater than a predetermined value, the valve plate 83 is elastically deformed and the spring is compressed, so that the high pressure fluid in the second pump chamber is adjusted to the pressure adjusting hole 81. ) And is discharged through the overpressure fluid recovery hole (82). Therefore, as shown in Figure 2, it is possible to maintain the pressure in the pump and the pipeline below a certain value without the cumbersome work of installing a separate safety valve 220 in the pipeline, thereby dramatically reducing the installation cost and installation process of the pump device Can be reduced.

FIG. 8 is a view showing another embodiment of the present invention, and unlike the embodiment of FIG. 3, the cylindrical body 11 is divided into a first pump chamber body 11a and a second pump chamber body 11b. And the 2nd pump chamber body 11b, the cover plate 15, and the cylindrical diaphragm 21 are integrally comprised.

In the case where the pump is made of metal such as stainless steel without injection molding with resin, the present embodiment is advantageous in view of the manufacturing process and manufacturing cost rather than the embodiment of FIG. In this case, the outer side of the cylindrical diaphragm serving as a fluid passageway may not have to be deep.

As described above, according to the diaphragm pump according to the present invention, it is possible to effectively prevent the pulsation of the discharged fluid, and to simplify the installation work of the equipment because there is no need to install a separate piping parts such as air chamber or safety valve and At the same time, installation costs can be reduced.

In addition, in the past, even if the air chamber is installed to reduce the pulsation phenomenon of the fluid, since the fluid is intermittently discharged from the diaphragm pump itself, breakage of the pipe due to water hammering is frequent and the noise is severe. Since the diaphragm pump discharges itself by reducing the pulsation of the fluid, it is possible to prevent breakage of the piping system in advance and to significantly reduce noise.

Although the present invention has been described using a specific type of diaphragm pump as an example for convenience of description, the present invention can be applied to other types of diaphragm pumps and other types of pumps in which pulsation of flow occurs due to the intermittent suction and discharge. Of course.

In addition, since the above embodiments are merely exemplary embodiments of the present invention, various modifications or changes are possible within the spirit and scope of the present invention as set forth in the claims.

Claims (3)

In the diaphragm pump in which the discharge of the fluid is intermittently by the forward and backward operation of the diaphragm, A cylindrical body; A partition wall partitioning the inside of the cylindrical body into a first pump chamber and a second pump chamber; A diaphragm disposed in the opening of the first pump chamber; Driving means for operating the diaphragm forward and backward; A cover plate coupled to the opening of the second pump chamber; A cylindrical diaphragm which is formed in a cylindrical shape with a lower portion opened and is formed inside the second pump chamber to form a pressure equalizing chamber in which compressed air is received; A suction port formed in said first pump chamber; Suction valve means for opening and closing the suction port; A discharge passage communicating the first pump chamber with the second pump chamber; Discharge valve means for opening and closing the first discharge path; And a discharge port formed in the second pump chamber. The method of claim 1, wherein the discharge valve means, A cylindrical valve body having one side open and a protrusion formed at the other side and a plurality of through holes formed around the protrusion; A check ball disposed to be movable in the valve body; A valve seat disposed in the opening of the valve body, A valve installation hole is formed in the dividing wall to communicate with the discharge passage, and the discharge valve means is disposed in the valve installation hole, and the protrusion of the valve body is formed by a lower surface of the cap coupled to the upper portion of the valve installation hole. The diaphragm pump characterized by being pressed downward, and the space around the said projection part in the said valve installation hole forms a part of the said discharge path. According to claim 1, wherein the cover plate is formed with a pressure adjusting hole and a high pressure fluid recovery hole, the valve plate which is elastically supported by a spring is provided on the outside of the pressure adjusting hole and the high pressure fluid recovery hole, the second pump When the pressure in the room is a predetermined value or more, the spring is compressed, the high-pressure fluid in the second pump chamber is discharged through the pressure adjusting hole and the high-pressure fluid recovery hole, characterized in that the diaphragm pump.