KR0155477B1 - Solenoidal pump - Google Patents

Abstract

The purpose of the present invention is to relieve the shortcomings of the pressure adjustment of the relief type, and include an intake valve and an outlet valve, and the solenoid pump pumps by the reciprocating movement of the piston by the electromagnetic force of the electromagnetic coil. On the passage on the discharge side of the control valve, a pressure regulator for adjusting the flow rate of the fluid flowing through the passage was provided. The pressure regulating valve is displaced by the hydraulic plunger which is pressurized on the discharge side, and thus the flow rate is changed. In addition, the hydraulic plunger is provided with a pressure adjustment spring that applies a force in the direction of starting injection of the pressure adjustment valve on the opposite side of the pressure adjustment valve.

Description

Electronic pump

1 is a front view of the electronic pump of the present invention.

2 is a plan view of the statue.

3 is a cross-sectional view cut longitudinally.

4 is a cross-sectional view cut in the transverse direction.

5 is a cross-sectional view of the regulator valve unit.

* Explanation of symbols for main parts of the drawings

1: Electronic pump 2: Electronic coil

26: suction valve 28: discharge valve

29: lid 62: pressure regulator valve (調壓 弁)

64: rod 65: hydraulic plunger

69: regulator valve unit

[Industrial use]

The present invention relates to an electronic pump using a solenoid (electromagnetic coil) for pressurizing kerosene and the like, in particular an electronic pump having a pressure adjusting function for maintaining a constant discharge pressure.

[Prior art]

The solenoid pump reciprocates the electromagnetic plunger and the pressure piston connected to the electromagnetic plunger by the intermittent electromagnetic force of the electromagnetic coil, and acts as a cooperative movement of the intake valve and the discharge valve. In order to maintain constant discharge pressure, the following methods were used.

It is a relief method that returns the excess flow back to the suction side, and it returns to the suction side through the relief valve from the discharge side as set forth in Japanese Chamber No. 51-23368, but it is set to a constant valve pressure. Piston strokes are constantly large and constant because the capacity is set above the required flow rate by compensating for reduced capacity due to temperature rise of the electromagnetic coil and compensating discharge pressure for fluctuations in input voltage (mainly ± 10%). Or cause noise.

In addition, since the piston stroke was large, it was necessary to install a pulsation preventing accumulator. In addition, the relief valve is mostly made of a soft material such as rubber in order to achieve the mechanical performance, and the life of the relief valve was limited due to the large deterioration effect. The breakdown of the relief valve lowered the discharge pressure and, when used in the combustor, caused incomplete combustion of the fuel.

[Problem of invention]

In order to eliminate the drawbacks of the conventional relief method, the present invention stops adopting this method and adopts a new pressure control method.

[Means for solving the problem]

The electromagnetic pump of the present invention includes an intake valve and a discharge valve, and pumps the pump by reciprocating the piston by the electromagnetic force of the electromagnetic coil, the flow rate flowing through the passage on the passage on the discharge side after the discharge valve. And a pressure regulating valve which is displaced by a hydraulic plunger which receives the pressure on the discharge side, and at the same time, the pressure plunger applies a pressure to the open valve direction of the pressure regulating valve on the semi-pressure valve side. It is provided with.

[Action]

Therefore, when the solenoid pump is driven, the piston reciprocates and cooperates with the suction valve and the discharge valve to pump and pressurize and discharge it from the discharge hole, but the fluctuation of the pressure moves the pressure control valve via the hydraulic plunger, thus The opening area is appropriately determined to maintain the pressure at the set pressure, and at the same time, the piston stroke is proportional to the discharge flow rate, so that the minimum piston stroke is required.

EXAMPLE

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described based on drawing.

In FIGS. 1-4, the electromagnetic pump 1 is equipped with the electromagnetic coil 2 through which an interruption current (pulse current) flows, and this electromagnetic coil 2 is wound by the resin bobbin 3 And a terminal 4 for power supply. In the center of the electromagnetic coil 2, a guide pipe 5 made of metallic material and nonmagnetic material is provided in the longitudinal direction.

An iron magnetic rod 40 is inserted into and in contact from the upper side of the guide pipe 5, and the eastern part of the discharge joint 45 described below is in contact with the upper end. In addition, the outer side at one end is in contact with the pump main body 9 via the zero ring 8.

The upper plate 11 and the lower plate 12 were disposed along the upper and lower portions of the bobbin 3, and made of a magnetic material such as iron provided on the outermost side of the electromagnetic coil 2 of the eastern portion 47 of the discharge joint 45. The magnetic circuit is constituted by (13). Furthermore, the case 13 is attached to the main body 9 by a spring 14.

The electromagnetic plunger 15 is a cylindrical body made of magnetic material such as iron, and is supported in the electromagnetic plunger operating chamber 17 composed of the guide pipe 5 such as the upper spring 16a and the lower spring 16b. It is in the state of FIG. 3 under no excitation.

The electromagnetic plunger operating chamber 17 is separated into an upper spring chamber 17a and a lower spring chamber 17b by the electromagnetic plunger 15. Vertical holes 19 are formed in the electromagnetic plunger 15 in the axial direction and communicate between the upper spring chamber 17a and the lower spring chamber 17b. In addition, the following piston 20 is firmly attached to the lower portion of the electromagnetic plunger 15.

As described above, the piston 20 is firmly attached to the electromagnetic plunger 15 and inserted into the cylinder 21, and reciprocates in accordance with the reciprocating motion of the electromagnetic plunger 15. Furthermore, the cylinder 21 supports the lower end of the lower spring 16b while supporting the pump body 9 via the 0-ring 22.

In the pump chamber 25, when the front end of the piston 20 forms one surface and the pump chamber 25 becomes negative pressure due to the reciprocating motion of the piston 20, the suction valve 26 opens to draw fluid from the suction hole 31. If the suction pressure is positive, the discharge valve 28 is opened and discharged through the through hole 61 in the plunger operation chamber 17.

The suction valve 26 and the valve 28 are housed in the suction valve valve unit integrated with the valve seats 26a, 28a and the lid 29, and have a hole 30 formed in the pump body 9. ) Is pressed and attached to the flat plate 36. In addition, the diameters of the holes 26b and 28b formed in the valve seats 26a and 28a are effective for bleeding air at 26b> 28b≥0.8mm.

The suction joint 32 in which the suction hole 31 is formed is inserted into the hole 33 formed in the pump main body 9, and is firmly attached to the main body 9 by the flat plate 34. Furthermore, the flat plate 34 is firmly attached to the main body 9 with a screw 35.

The magnetic rod 40 was made of a magnetic material such as iron and attached to the upper end of the above-described guide pipe 5 and the body 47 of the discharge joint 45 via the 0-rings 41 and 42. The hole 43 is formed in the inner and vertical direction. The discharge joint 45 has a main body 64 and a eastern part 47 connected thereto, and the eastern part 47 is inserted into the bobbin 3 so that the eastern part 47 has a magnetic rod inside thereof. It fits in the 40 and is pressed together with the upper plate 11 by the case 13 inserted inward from the electromagnetic coil 2 from the outside. The solenoid valve storage chamber 48 is formed in this discharge joint 45, and the solenoid valve 50 is accommodated.

The solenoid valve 50 is made of a movable iron piece 51a and a rubber-like valve 50b. The valve 50 is pressurized by the spring 51 and seated on the valve seat 52 to discharge the outlet 53. To close it.

Next, when the interruption current (pulse current) of the half-wave rectified commercial power is energized by the electromagnetic coil 2 as described above, a magnetic force is generated in the electromagnetic coil 2 when the current (pulse) is applied. The magnetic circuit of the lower plate 12 of the case 13, the magnetic plunger 15, the magnetic rod 40, the discharge joint 45, and the upper plate 11 is constituted, and the electromagnetic plunger 15 is attracted to the magnetic head side. Is displaced.

Repulsive energy is stored in the upper spring 16a in accordance with the displacement of the electron plunger 15 toward the magnetic rod side. In this case, the piston 20 is also displaced at the same time to open the suction valve 26 and the fluid is sucked into the pump chamber 25 via the suction hole 31. When the current (pulse) is interrupted, when the magnetic force of the electromagnetic coil 2 attenuates and disappears, the electromagnetic plunger 15 and the piston 20 are moved downward by the upper spring 16b.

Accordingly, the sucked fluid is pressurized to open the discharge valve 28 to be discharged into the plunger operating chamber 17. By repeating such an operation, for example, by vibrating 50 times per second (reciprocating motion), the piston 20 also reciprocates together, so that the fluid is pumped by the suction valve 26 and the discharge valve 28 to suck the fluid into the suction hole 31. ) Is discharged from the discharge hole 53. This electronic pump has the capability of supplying about 2 L to 5 L mesh.

Next, the parts related to the present invention will be described. As shown in FIGS. 4 and 5, the pressure adjusting mechanism 60 communicates with the through-hole communicating from the wake side to the plunger operating chamber 17 at the discharge valve 28. A pressure regulator 62 is provided on the through hole 61, and the pressure regulator valve 62 and the shrinkage hole 63 restrict the flow path area appropriately. To control the flow rate. The pressure regulating valve 62 is made of resin, and its tip abuts against the hydraulic plunger 65 via the rod 64 through which the shrinkage hole 63 is inserted, and is moved to the transition of the hydraulic plunger 65.

The pressure regulating valve 62 is disposed in the pressure regulating valve unit 69 integrated with the resin valve seat 63a in which the shrinkage hole 63 is formed and the resin cap 67, and the pump body 9 Is fitted into the hole 68 formed in (). The lid 67 side is pressed tightly by a flat plate 36 firmly attached to the pump body 9. Reference numeral 70 is a spring, which presses the pressure regulating valve 62 toward the shrinkage hole 63. 71 is a 0-ring provided in the valve seat 66 and the lid 67. The hydraulic plunger 65 is disposed in the cylinder 72 formed in the main body 9 so as to be freely slidable, made of resin, and kept airtight by the 0-ring 73.

The hydraulic plunger 65 is disposed in the cylinder 72, and is divided into a hydraulic chamber 75 on the shrinkage hole side and a spring chamber 76 on the opposite side of the shrinkage hole, but the hydraulic chamber 75 is not shown in the figure. It communicates with the plunger operating chamber 17 mentioned above. In the spring chamber 76, the adjustment spring 77 is accommodated, and the pressure spring 77 presses the hydraulic plunger 65 in the direction of the adjustment valve. Therefore, the adjustment valve 62 is a spring 70 having a small load. ) Is moved to the leftmost (FIG. 4), and the opening of the contraction hole 63 is the maximum (during pump ratio driving).

The pressure adjusting screw 78 is screwed into a flat plate (screw hole processing) 79 held tight by the flat plate 34, and comes into contact with the end of the pressure adjustment spring 77 via the spring support 80, and adjusts the pressure. By rotating the screw 78, the setting force of the adjustment spring can be adjusted, and the discharge pressure can be adjusted. Reference numeral 81 denotes a fixing nut of the pressure adjusting spring 78, and 82 a zero ring installed on the spring support 80.

In the pressure adjusting mechanism 60 in the above-described configuration, if the pressure force increases due to some cause (voltage rise), the pressure between the nozzle and the pump chamber 25 depends on the fluid resistance of the nozzle or the like. This becomes high, and the hydraulic plunger 65 displaces against the pressure regulation spring 77, and this displacement amount is transmitted to the pressure regulation valve 62 via the rod 64, and the pressure regulation of the pressure regulation valve 62 is reduced. In a direction to restrict the passage flow rates of the shrinkage hole 63 and the adjustment valve 62 to regulate the supply to the nozzle, and the discharge pressure is automatically adjusted to the set pressure. Furthermore, when the pressure regulator valve 62 is contracted, the pressure in the pump chamber 25 increases, so that the stroke of the piston 20 becomes small, and the suction amount is reduced compared to the discharge amount.

On the contrary, if the pressure between the discharge hole 53 and the pump chamber 25 drops, the balance with the pressure adjustment spring 77 for pressing the pressure plunger 65 is broken, and the pressure plunger 65 with the pressure adjustment spring 77 is broken. Is pressurized, and the pressure regulator 62 is moved in the direction in which the contraction action is alleviated to increase the flow rate of the passage, so that the discharge pressure is automatically adjusted to the set pressure. Moreover, when the contraction action of the pressure regulator valve 62 is alleviated, the pressure in the pump chamber 25 decreases, so that the stroke of the piston 20 becomes large, and the suction amount is increased compared to the discharge amount. Furthermore, the above-described movement of the pressure regulating valve 62 is varied by several microns so that the flow rate is controlled. The discharge pressure is adjusted by rotating with the pressure adjusting screw 78, whereby the discharge pressure can be adjusted to an arbitrary set pressure. Moreover, 84 is a pulsation preventing accumulator, 85 is an air bleed valve.

[Effects of the Invention]

According to the present invention as described above, even if the electromagnetic pump causes a pressure change for any reason, the pressure regulating valve is changed via the hydraulic plunger, so that the opening area of the shrinkage hole can be controlled to maintain the set pressure.

In addition, since the pressure control does not employ a relief method, it becomes a piston stroke proportional to the discharge flow rate and can reduce vibration noise.

In addition, since the pressure regulator valve and the hydraulic plunger are resins, the manufacturing cost is reduced.

In addition, since the regulator valve is housed in the regulator valve unit, attachment to the pump body is easy.

Claims (3)

A solenoid pump having a suction valve and a discharge valve and pumping the piston by a reciprocating motion of the piston by the electromagnetic force of the electromagnetic coil, the pressure control valve for adjusting the flow rate of the passage on the passage on the discharge side after the discharge valve. The pressure valve is displaced by a hydraulic plunger receiving the pressure on the discharge side, and the hydraulic plunger is provided with a pressure spring on the semi-pressure valve side to apply a force in the open valve direction of the pressure valve. An electronic pump characterized in that the valve seat and the lid are housed in an integrated pressure regulating valve unit and disposed in a hole formed in the pump body. The electromagnetic pump according to claim 1, wherein the pressure regulator valve and the hydraulic plunger are made of resin. The electromagnetic pump according to claim 1, wherein a rod is integrated with the pressure regulator valve, and the tip of the rod is brought into contact with the hydraulic plunger.