KR100869005B1 - The method and structure of preventing water from leakage for the pressurized pump of diaphragm type - Google Patents

Abstract

The present invention provides a method and a structure for preventing leakage of a diaphragm type pressure pump; In this method, corresponding to the helical hole in each rocking plate, a hollow cylinder is first installed on the upper surface of each piston operating region of the diaphragm seat; Forming a ladder hole of a piston head pressurized chunk of a diaphragm seat on an outer circumference of the hollow cylinder; Drive a set screw through a central hole of the hollow cylinder to a spiral hole on each swing plate of a diaphragm type pressure pump; At the beginning of the driving of the fixing screw, the upper portion of the hollow cylinder is first expanded; The fixing screw is driven completely into the spiral hole on the rocking plate, and then the upper portion of the hollow cylinder is expanded to fill the space between the bottom surface of the head of the fixing screw and the upper surface of the ladder hole of the piston head press chunk. do. Therefore, since the hollow cylinder performs the functions of the water leakage blocking device and the water inflow blocking device into the motor, it is possible to avoid the damage of the diaphragm type pressure pump due to the electric short circuit of the motor.

Oscillating plate, cylinder, piston, ring, hood, chassis, port, rib

Description

Leakage prevention method and structure of diaphragm type pressure pump {THE METHOD AND STRUCTURE OF PREVENTING WATER FROM LEAKAGE FOR THE PRESSURIZED PUMP OF DIAPHRAGM TYPE}

1 is an enlarged perspective view of a conventional diaphragm pressure pump.

2 is a cross-sectional view of the conventional piston valve body of FIG.

Figure 3 is a view showing an internal cross-sectional view of the pump cover body in a conventional diaphragm type pressure pump.

4 is a view showing a first operation of a conventional diaphragm type pressure pump.

Figure 5 is a view showing a second operation of the conventional diaphragm type pressure pump.

6 is an enlarged perspective view showing a piston head pressurized chunk having a diaphragm seat and a rocking plate in a conventional diaphragm pressurized pump.

7 is a cross-sectional view of the assembly of FIG.

8 is a partially enlarged cross-sectional view of FIG.

Figure 9 illustrates the operation of Figure 8;

10 is a partially enlarged sectional view of FIG. 5;

Figure 11 is a perspective view of the present invention.

Figure 12 illustrates an embodiment of the present invention.

FIG. 13 is a partially enlarged sectional view of FIG. 12; FIG.

Figure 14 illustrates the operation of Figure 13;

Figure 15 illustrates a first operation of the present invention.

16 and 17 show a second operation of the present invention;

Figure 18 illustrates a first operation of another exemplary embodiment of the present invention.

Figure 19 illustrates a second operation of another exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: motor 13: rocking plate

20, 60: diaphragm sheet 31: ladder hole

40: valve body 60: seat

64: cylinder 70: washer

W: Supply water

The present invention relates to a diaphragm pressurized pump exclusively used for reverse osmosis purification, and in particular, has a disadvantage in that durability is reduced in premature defect damage due to an electrical short circuit due to leakage into a motor which is always generated in a conventional pressurized pump. In order to completely overcome, the present invention relates to a pressure pump having a diaphragm function to prevent leakage into a motor.

Diaphragm pressure pumps exclusively used for reservoir osmosis purification are described in U.S. Pat.Nos. 4.396.357, 4.610.605, 5.376.367, 5.571.000, 5.615.597 and 5.602.464. Nos. 5.49.812, 5.606.715, 5.917.882, 5.616.133, 6.048.183, 6.089.838, 6.299.414, 6.604.909, No. 6,724.745, 6,92,624, and the like. The structure for this is shown in Figs. An upper hood chassis 11 disposed at an end of the motor 10, an output shaft (not shown) of the motor 10, at least one screw bore 12 on the outer periphery of the upper hood chassis 11, A swing plate 13 which is converted to an axial reciprocating motion in the upper hood chassis 11 and driven by an output shaft of the motor 10, a diaphragm seat 20 covering the upper hood chassis 11; And a piston head pressurized chunk 30 disposed on the diaphragm seat 20, a piston valve body 40 inserted into the diaphragm seat 20, and a pump cover body 50. By means of the bolt 2 actuated through the screw bore 12 in the upper hood chassis 11 and the corresponding through-hole 51 of the pump cover body 50, all of the components described above are integrated body. As assembled (shown in FIG. 2).

The ring of the sealing groove ridge bar 21 is installed at the top of the outer periphery in the diaphragm seat, and the ridge rib 22 is radially installed from its upper center to the connection with the sealing groove ridge bar 21, thus actuating the piston. Region 23 is defined by the raised ribs 22 and the sealing groove raised bars 21. In addition, the central through hole 24 is aligned with the helical hole 14 of each rocking plate 13 and punched on the piston operating region 23. By means of respective fixing screws 3 actuated through the inner ladder hole 31 of the respective piston head press chunk 30 and the corresponding central through hole 24 of the respective piston actuating region 23, The diaphragm seat 20 and the piston head actuating chunk 30 may be screwed into the helical hole 14 in the swinging plate 13 (shown in FIG. 2).

In addition, the hemispherical concave water drain base 41 facing the pump cover body 50 is provided in the center of the piston valve body 40 having a positioning hole 42 in the center thereof, Since the grooves 43 are each formed at a narrow angle of 120 ° along the radial line from the center thereof, three spaced apart zones are separated by the concave grooves 43, and the water drain port 44 is separated from the spaced zones. A water inlet port 45 is formed on the outer periphery corresponding to each water drain port 44, and an inverted flare piston seat 46 is formed at the center of each water inlet port 45. As perforated in, each of the flared piston seats 46 may block the water inlet port 45. Inverted baffle plastic pads 47, which are soft elastic hollow hemispheres of a unitary body with positioning poles 48 protruding from the bottom center, are in close contact with the upper surface of the water drain base 41 in the piston valve body 40. And the partition rib plate 49 is formed at a 120 ° narrow angle along its radial line from the center thereof, so that three spaced apart zones are separated by the rib plate 49 and protruding pegs 481. Is formed on the outer circumferential surface of each rib plate 49. Reverse baffle plastic pads 47 by inserting each protruding peg 481 into a corresponding concave groove 43 and plugging the positioning poles 48 into the positioning holes 42 in the water drain base 41. The hemispherical surface outside of will be in intimate contact with respect to all water drain ports 44 in each zone of the water drain base 41 (shown in FIG. 2). The water inlet chamber 100 is a reversal baffle plastic pad 47, all water drain ports 44 in each zone of the water drain base 41, and piston head pressurized chunks of the diaphragm seat 20. Formed between 30 (shown in FIG. 3); One end of each water inlet chamber 100 is connected to each water inlet port 45.

Further, a plurality of through holes 51 and water inlet orifices 52 are formed on the outer surface of the pump cover body 50 as shown in the water outlet orifice 53 (shown in FIGS. 1 and 3), and the cover body The ladder groove 54 and the annular groove 55 is formed therein; Since the ladder groove 54 is formed on the bottom main surface of the pump cover body 50, the annular groove 55 is a piston to be in close contact with the outer circumferential surface of the piston valve body 40 and the diaphragm seat 20 assembly. Since the valve body 40 is formed at the inner center of the bottom which is pressed against the outer circumferential surface of the water drain base 41, the high pressure water chamber 200 is formed on the inner wall of the annular groove 55 and the piston valve body 40. Is surrounded by a space between the water drain base 41 of FIG.

4 and 5 show a method of operating a conventional diaphragm type pressure pump as described above. When tap-water flows from the pump cover body 50 into the water inlet orifice 52, the tap-water presses the flared piston seat 46 at the open piston valve body 40, and the piston valve body 40 ) Flows through the water inlet port 45 into the interior of the water inlet chamber 100 (shown in FIG. 4). With all the swinging plates 13 sequentially driven by the output shaft of the motor 10, the piston head pressurized chunks 30 in the respective swinging plates 13 are in axial reciprocating motion, so that the diaphragm seat ( Each piston operating area 23 in 20) is vibrated simultaneously to squeeze the water in the water inlet chamber 100 to increase the water pressure from 80 psi to 100 psi. The high pressure water Wp presses the anti-reversal baffle plastic pads 47 in the open water drain base 41 and in the water drain base 41 through each water drain port 44 a high pressure water chamber. It flows into 200 and is then discharged from the pressurized pump through each water outlet orifice 53 in the pump cover body 50 to provide the necessary water pressure for reverse osmosis by the RO membrane cartridge RO in the RO filter device. (Shown by arrows in Figure 5)

However, the diaphragm pressurized pump described above as shown in Figs. 6 to 9 generally has serious drawbacks. During the process of increasing the water pressure after starting of the motor 10, each rocking plate 13 is in intimate contact with the diaphragm sheet 20, so that the rocking plate 13 moves during the reciprocating motion, so that the diaphragm sheet ( Each time driving the piston operating region 23 at 20, the diaphragm seat 20 between the piston operating region 23 and the oscillating plate 13 is towed and unfolded once (shown in phantom in FIG. 8). Thus, the diaphragm sheet 20 will be towed to unfold 700 times per minute when the rotational speed is 700 rpm. Thus, the diaphragm seat 20 will be in loose contact with the piston head pressurized chunk 30 without hermetic sealing due to prolonged frequent unfolding (shown in FIG. 9). Thus, the high pressure water Wp will leak along the gap between the set screw 3 and the helical hole 14 in the swinging plate 13, resulting in the entire diaphragm pressurized pump and the electric of the motor 10. It will damage the short circuit by disabling it. Because of this drawback of having an ineffective solution in the manufacturing industry, consumers have no choice to buy their own good luck in purchasing pressurized pumps with uncertain life. If the consumer has suffered the misfortune of burning the motor 10 due to leakage, the risk of fire cannot be ignored.

In addition to the drawbacks described above, as shown in Fig. 10, the piston valve body 40 and the pump cover body 50 are in a position containing another problem of leakage. When the piston operating region 23 in the diaphragm seat 20 is continually pressurized and compressed by the swing plate 13, the upper outer circumferential surface of the piston valve body 40 is formed by the ladder groove ( 54) continuously hitting and towing the walls of (indicated by arrows in FIG. 10), and the piston valve body 40 and the pump cover body 50, which are rigid bodies without a buffer structure device, cause mutual long-term repeated strokes and The gap will be easily created after the towing. Under high pressure water operation, water leaks and leaks water from the diaphragm pressurized pump through a gap between the wall of the ladder groove 54 on the pump cover body 50 and the upper peripheral surface of the piston valve body 40. Will come out. Therefore, this partial pressure loss reduces the overall hydraulic pressure increase effect.

It is a main object of the present invention to provide a method and structure for preventing leakage of a diaphragm type pressure pump; In this method, corresponding to the helical hole in each rocking plate, a hollow cylinder is first installed on the upper surface of each piston operating region of the diaphragm seat; Forming a ladder hole of a piston head pressurized chunk of a diaphragm seat on an outer circumference of the hollow cylinder; Drive a set screw through a central hole of the hollow cylinder to a spiral hole on each swing plate of a diaphragm type pressure pump; At the beginning of the driving of the fixing screw, the upper portion of the hollow cylinder is first expanded; After the fixing screw is completely driven into the spiral hole on the rocking plate, the upper portion of the hollow cylinder is deformed to fill the space between the bottom surface of the head of the fixing screw and the upper surface of the ladder hole of the piston head press chunk. do. Therefore, since the hollow cylinder performs the functions of the water leakage blocking device and the water inflow blocking device into the motor, it is possible to avoid the damage of the diaphragm type pressure pump due to the electric short circuit of the motor.

Another object of the present invention to provide a method and structure for preventing leakage of a diaphragm type pressure pump is to provide an elastic soft washer between the outer circumferential surface of the piston valve body and the wall of the ladder groove on the pump cover body. In addition to reducing the hard blow force and noise by the pump cover body and the piston valve body, the airtight sealing effect can be achieved in terms of prevention of leakage and pressure loss of the pressure pump.

11 to 13 show an embodiment of the present invention showing a method and a structure for preventing leakage of a diaphragm type pressure pump. Corresponding to the helical apertures 14 of each rocking plate 13, since the hollow cylinder 64 is first installed on the upper surface of each piston operating region 63 of the diaphragm seat 60, its outer diameter is the piston It is equal to or slightly smaller than the inner diameter of the ladder hole 31 in the head press chunk 30. The hollow cylinder 64 and the diaphragm seat 60 are made of the same plastic material in the extruded integrally molded body (shown in FIGS. 11 and 12A) and pressurized piston head chunks on the outer circumference of the hollow cylinder 64 After forming the ladder hole 31 of 30 (shown in FIG. 12B), the fixing screw 3 is moved into the spiral hole 14 of the swing plate 13 through the center hole of the hollow cylinder 64. Drive it. At the beginning of the drive of the set screw 3, the top of the hollow cylinder 64 will first be expanded; After the fixing screw 3 is completely driven from each rocking plate 13 into the inside of the spiral hole 14, the upper portion of the hollow cylinder 64 extends the deformation so that the bottom of the head of the fixing screw 3 is extended. The space between the face and the upper face of the ladder hole 31 of the piston head press chunk 30 is filled (shown in Figs. 12D and 13). Thus, the hollow cylinder 64 performs the function of a blocking device for blocking leakage.

14 to 16, when the oscillating plate 13 acts to pressurize and extrude the feed water W (shown in Fig. 16), the diaphragm seat 20 of the piston operating region 23 simultaneously Pressurized so as to be displaced, a gap δ is formed between the bottom face of the piston head press chunk 30 and the top face of the diaphragm seat 20; By enclosing the blocking function of the expansion deformation of the upper portion of the hollow cylinder 64, it is possible to avoid leakage occurring along the gap between the spiral hole 14 and the fixing screw 3 in the swinging plate 13; Accordingly, an effect of preventing damage to the pressure pump in the electrical short circuit of the motor 10 may be achieved due to leakage of high pressure water Wp and inflow of water into the motor 10.

17 to 19, the present invention provides a buffer area by providing an elastic soft washer 70 between the outer circumferential surface of the piston valve body 40 and the wall of the ladder groove of the pump cover body 40, thereby providing a pump area. In addition to reducing the hard blow force and noise by the cover body 50 and the piston valve body 40, it is possible to achieve a hermetic sealing effect in terms of preventing leakage and pressure loss of the pressure pump.

 In conclusion, the present invention provides a hollow cylinder 64 to replace the through-hole in the center of the piston operating region 23/63 in the diaphragm seat 20/60, and inherently identical to form a leakage resistance structure. Use assembly steps. Therefore, it is an innovative invention with industrial application value because it not only eliminates the extra expense in manufacturing cost but also achieves the effect of leakage resistance.

Claims (3)

In the method for preventing the leakage of the diaphragm type pressure pump, (1) Corresponding to the spiral hole in each rocking plate, firstly a hollow cylinder is installed on the upper surface of each piston operating region of the diaphragm seat, (2) forming a ladder hole of the piston head press chunk of the diaphragm sheet on the outer circumference of the hollow cylinder, (3) drive the set screw through the central hole of the hollow cylinder into the spiral hole on each rocking plate of the diaphragm type pressure pump; (4) at the beginning of the driving of the fixing screw, the upper portion of the hollow cylinder is first expanded; After the fixing screw is completely driven into the spiral hole on the rocking plate, the upper portion of the hollow cylinder is deformed to fill the space between the bottom surface of the head of the fixing screw and the upper surface of the ladder hole of the piston head press chunk. Thus, the hollow cylinder is a leakage preventing method, characterized in that to perform the function of the blocking device to prevent leakage. 2. The hollow cylinder and the diaphragm sheet are made of the same elastic plastic material in the unitary molded body extruded in step (1), wherein the outer diameter of the hollow cylinder is equal to the inner diameter of the ladder hole of the piston head press chunk. Leakage prevention method characterized in that or slightly smaller than this. In the structure for preventing leakage of the diaphragm type pressure pump, Motor, An upper hood chassis disposed at one end of the motor and having one or more threaded bores around its periphery; At least one rocking plate pivoted in the upper hood chassis and driven by an output shaft of the motor and converted into axial reciprocating motion; A diaphragm seat covering the upper hood chassis, the diaphragm seat having a ring of sealing groove ridge bars in engagement with the sealing groove ridge bars so that at least one piston operating area is partitioned by ridge ribs and sealing groove ridge bars; , One or more piston head pressurized chunks formed in the diaphragm seat, A piston valve body inserted into an upper surface of the diaphragm seat; A pump cover body having a through hole and a water inlet orifice as well as a water outlet orifice formed on the outer side; The piston valve body has a positioning hole at the center thereof and a water drain base facing the pump cover body installed at the center; The concave grooves for the partitions are each formed at a narrow angle of 120 ° along the radial line from the center thereof, so that three spaced apart areas are separated by the concave grooves; A water drain port 44 is formed in said spaced region, and a water inlet port is formed on the outer circumference corresponding to each water drain port; The inverted flared piston seat is drilled in the center of each water inlet port; The anti-reversal baffle plastic pad, which is tightly inserted into the upper surface of the water drain base, is a soft elastic hollow hemisphere of the unitary body having a positioning pole projecting from the bottom center; The partition rib plate is formed at a 120 ° narrow angle along the radial line from the center thereof; Protruding pegs are formed on the outer circumferential surface corresponding to each rib plate; A water inlet chamber is formed between the anti-back baffle plastic pad, all the water drain ports in each zone of the water drain base, and the piston head pressurized chunk of the diaphragm seat; One end of each water inlet chamber is connected to each water inlet port; A ladder groove is formed at the bottom periphery; Since the annular groove is formed on the bottom in close contact with the outer circumferential surface of the water drain base in the piston valve body at the inner center, the high pressure water chamber is surrounded by the space between the water drain base of the piston valve body and its inner wall, By driving the bolt through at least one screw bore of the upper hood chassis and a corresponding through hole preset in the pump cover body, all parts are screwed and assembled into an integral body; Corresponding to the helical hole of each rocking plate, the hollow cylinder is formed on the upper surface of each piston operating region of the diaphragm sheet, the leakage preventing structure of the diaphragm type pressure pump.

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