KR0171554B1 - Electromagnetic pump - Google Patents

Abstract

The purpose is to allow the internal pressure of the pump to run upstream from the intake valve when the pump is stopped.

A leak space is installed on the piston reciprocated by the electromagnetic coil, and the leak space is inserted into the leak cylinder so that the leak space is defined as one part of the leak space of the tip and the leak cylinder. Connected to the upstream side.

Description

Electronic pump

1 is a longitudinal sectional view showing an embodiment of the present invention.

2 is a cross-sectional view of the main part of the statue.

3 is a cross-sectional view showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: electromagnetic pump 2: electromagnetic coil

15: electromagnetic plunger 24: cylinder

28: suction valve 29: discharge valve

38: leaky Sophie 39: leak cylinder

40: leak space 60: electromagnetic valve

64: pressure rise time adjusting device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic pump, in particular an electromagnetic pump having a shutoff valve to stop the discharge of the fluid when the pump is stopped.

The electromagnetic pump reciprocates the piston by using the intermittent suction force generated in the electromagnetic coil by the intermittent current to perform a pumping action as a cooperative operation between the suction valve and the discharge valve. . In the conventional solenoid pump, the solenoid valve was installed after the discharge hole and the pump was stopped at the same time as the pump was stopped. However, due to the two components, the structure was enlarged and the applicant had a built-in solenoid valve. 52-38243) have been developed and are currently in use and are now in the midst of electronic pumps.

Such an electromagnetic valve with a built-in solenoid valve is widely used for oil burners of combustion equipment such as hot water heating and the like. In recent years, with the advance of combustion technology of burner, the equipment adopting the ona ignition method to reduce the noise and pollution exhaust gas in the early stage of combustion has become mainstream. have.

One is called mechanical type, and pump discharge pressure acting air injection with combined volume and orifice leakage function in the main body of an electronic pump is disclosed, for example, in Japanese Patent Application Laid-Open No. 59-7787 (electronic pump having a pressure rise time adjusting device), and seal 62-14173 (electronic Pressure rise time adjustment device of pump) and actual place 62-184180 (rise time adjustment device of an electronic pump) are mechanically actuated.

The other is to call the electric pump, and to control the duty ratio of the start-up or pulse current of the pump using the above-described electronic pump by using a control circuit and electrically actuate the discharge pressure of the pump.

Both acting copper technologies have their own characteristics, but the commonalities of both methods are that the discharge hole is closed by the transfer valve installed at the time of stopping the electronic pump, so that high pressure (for example, about 7kg / ㎠) Each has a pressure release means.

In the mechanical actuating technique, the return passage is opened as a pressure and return spring before and after the mffjwj with an orifice in the volume change plunger and the residual pressure is opened to the suction side.

In the electric actuating technique, for example, a small leak hole is provided in advance in the relief valve of the electronic pump, as shown in, for example, Japanese Patent Application No. 58-82481 (pump residual pressure eliminator), or Japanese Patent Application Laid-Open No. 1-166777 (Electronic pump). As shown in (Voltage Relief Relief Valve), an orifice is provided between the inside of the pump and the suction path, and it leaks on the suction path side even during the pump operation.

Since the dedicated leakage path or orifice has one effective opening area, it is easy to accumulate dust, etc. Therefore, a strainer (filter) is usually provided exclusively immediately before or in front of the magnetic field. However, the on-off control frequency of the electronic pump has been responding to a good design of about 200,000 times. However, it exceeds this much, and more than 1 million repetitive operations are required for practical use, due to the influence of the fine abrasion of the internal movable part of the electronic pump itself. The scale is so tight that it is impossible to release the internal pressure, causing irrational points.

Accordingly, an object of the present invention as set forth in claim 1 is to provide an electropump which provides a self-cleaning furnace for internal pressure release and at the same time performs a self-cleaning action to prevent the scale from being worn. The invention described in claim 2 shows an example in which a mechanical pressure rise time adjusting device is added as an electromagnetic pump having the object of the invention according to claim 1.

In order to achieve the above object, the invention described in claim 1 is an electromagnetic plunger reciprocated by energization of an intermittent current in an electromagnetic coil, and a piston reciprocating in a cylinder in cooperation with the electronic plunger and the piston. In the solenoid pump having a suction valve and a discharge valve acting as a pump, and a shutoff valve for turning off the discharge port when the electronic pump is stopped, a leaky Sophie stone is installed at the tip of the piston so that the leaky piston is provided with a sliding cylinder. At the same time as the insertion, the tip of the leaky Sophie stone and the leak cylinder are one part, and the planetary leak space is communicated upstream from the suction valve. Moreover, the invention of Claim 2 adds the pressure rise time adjustment apparatus to the structure of invention of Claim 1.

Therefore, in the invention described in claim 1, the pump internal pressure enters the pump chamber through the clearance between the piston and the cylinder and is discharged upward from the intake valve through the clearance between the leaky sophie and the leak cylinder. That is, the clearance between the piston and the cylinder, the clearance between the pump chamber, and the leaky Sophie stone and leak cylinder can be a leakage path, and the pump internal pressure can be reduced within a predetermined time. In addition, since the leaky Sophie Stone always reciprocates in the leak cylinder when the pump is driven, no dust or the like is attached. Even if it is attached, it becomes a self-cleaning action and there is no mail on the scale.

The invention described in claim 2 is an electronic pump in which a volume change occurs in the initial stage of the pump driving to smooth the pressure rise, by adding a mechanical pressure rise time adjusting device. In addition, it is possible to function the pressure rise time adjusting device which is discharged from the leakage path formed between the gap between the leaky sophiestone and the leak cylinder.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described by drawing. In FIG. 1 and FIG. 2, the electromagnetic pump 1 has the electromagnetic coil 2 to which the short-circuit current (pulse current) is applied in the case 4 formed from magnetic materials, such as iron. The electromagnetic coil 2 is formed by winding an electric wire around a resin bobbin 3. A through hole formed through the center of the bobbin 3 has a metal guide pipe 5 interposed therebetween. . In addition, the upper plate 6 and the lower plate 7 are arranged on the upper and lower ends of the electric bobbin 3 to form a magnetic circuit like the case 4.

A magnetic rod 8 is disposed above the guide pipe 5 and inserted into the pump body 10 via an O-ring 9 at the lower end of the guide pipe 5. The magnetic rod 8 is formed of a magnetic material such as iron so that almost the lower half of the magnetic rod 8 is sandwiched in the guide pipe 5 via the O-ring 11 and the magnetic rod 8 The remaining upper half is through the O-ring 12 and the discharge joint 56 is inserted in the eastern part 58, and the hole 13 penetrates in the longitudinal direction inside.

The electromagnetic plunger 15 is formed in a substantially cylindrical shape by a magnetic material such as iron, and is formed in the electromagnetic plunger operating chamber 19 formed in the guide pipe 5 by the upper spring 16 and the lower spring 17. It is supported to slide. The electromagnetic plunger operating chamber 19 is divided into an upper spring chamber 19a and a lower spring chamber 19b by the electromagnetic plunger 15. A longitudinal hole 20 is drilled in the electromagnetic cleaner 15 in the axial direction, and the upper spring chamber 19a and the lower spring chamber 19b communicate with each other. In addition, the piston 21 is fixed to the lower portion of the electromagnetic plunger 15.

The piston 21 is inserted into the cylindrical cylinder 24 sandwiched through the O-ring 23 in the hole formed in the pump body 10 to reciprocate in accordance with the reciprocating motion of the electromagnetic plunger 15. The cylinder 24 is inserted into the hole 22 communicating with the electromagnetic plunger operation chamber 19 formed in the pump body 10 so that the plunger 25 formed on the outer circumference of the pump body 10 is O at the pump body 10. It is engaged via the ring 23. The plunger 25 also serves to support the lower end of the lower spring 17.

The pump chamber 27 is a space formed by the tip of the pump body 10 and the piston 21 and the leak piston 38 and the leak cylinder 39 described below, and the volume thereof is reciprocated by the reciprocating motion of the piston 21. In other words, the pump works in cooperation with the intake valve 28 and the discharge valve 29. Specifically, when the piston 21 is raised to enlarge the volume of the pump chamber 27 and the negative pressure inside the pump chamber 27 is opened, the suction valve 28 is opened to suck the fluid (fuel) from the suction hole 30, and the piston 21 ) Is lowered to decrease the volume of the pump chamber 27 and the pump chamber 27 is at a constant pressure to open the discharge valve 29 to discharge the fuel.

The suction valve 28 and the discharge valve 29 are combined with the toilet body 28a and 29a, and the suction valve 31 is formed by integrating the lid 31 into the toilet body 29a on the discharge side. ) Is pressed and housed in the hole 33 formed in the pump body 10 by the attachment plate 36 tightened with the screw 35 to the pump body 10. The flow path between the intake valve 28 and the discharge valve 29 communicates with the pump chamber 27.

28b and 29b are springs. The flow path after the discharge valve 29 is communicated with the electromagnetic plunger operating chamber 19, not shown.

The leaky Sophie 38 is attached to the tip of the piston 21 and protrudes in the coaxial direction. The leaky Sophie 38 is inserted into the leak cylinder 39 and reciprocated in the leak cylinder 39. The leak cylinder 39 is inserted into the seal 22, and the upper portion of the leak cylinder 39 is formed as one part for defining the pump 27, and a part of the leak space 40 at the other end. The leak space 40 communicates with the upstream of the suction valve 28 in the flow passage 46.

The gap between the leak piston 38 and the leak cylinder 39, that is, the diameter of the leak piston 38 and the diameter of the leak cylinder 39, is related to the length of the leak cylinder 39, but it is 2 to 3 seconds. It is necessary to determine the amount within which the pump internal pressure falls to atmospheric pressure within a short time.

The relief valve 41 is formed from the relief valve body 42 and the adjusting screw 43 including the relief valve body 42. The relief valve body 42 is a spring 44 and the discharge pressure (high pressure) is downstream from the discharge valve 45. ) Is pressed against the supplied nozzle 45 to extract the pressure after the discharge valve 29 and to maintain a predetermined pressure (for example, 7 kg / cm 2). The surplus fuel oil is returned to the upstream side of the intake valve 28.

47 is an accumulator, which is inserted into the flow path after the discharge valve 29 for smoothing the discharge pulsation, and the diaphragm 48 is interposed between the attachment portion 49 and the case 50 to provide an elastic body in the room on the case side. It is formed by putting (51). The attachment portion 49 is inserted into the pump body 10 through the ring 53 through the ring opening 53, and is pressed against the attachment plate 36, which is retained from the rear, and the accumulator 47 is fixed. have.

The discharge joint 56 has a main body 57 and an eastern portion 58 connected thereto, and the eastern portion 58 is inserted into the bobbin 3 and the upper portion of the magnetic rod 8 is fitted as described above. . In addition, the solenoid valve accommodating chamber 59 is formed in the eastern part 58. The solenoid valve 60 is accommodated in the solenoid valve accommodating chamber 59 and pressed by a spring 61, and the discharge hole 62 is closed. When closing (non-energizing) and energizing, the discharge hole 62 is opened by pulling on the spring 61 on the magnetic rod 8 side.

As described above, when the pulse current having a predetermined number of pulses (50 to 60 times) is applied to the electromagnetic pump 1 and the electromagnetic coil 2 is excited, a magnetic force is generated in the magnetic rod 8 to generate an electromagnetic plunger. (15) is pulled into the upper spring 16 and sucked, and repulsive energy is accumulated in the upper spring 16. Thus, when the electromagnetic coil 2 is demagnetized, the attraction force disappears and is returned downward by the repulsive energy of the upper spring 16. By this repetition, the electronic plunger 15 reciprocates. In addition, the electromagnetic pump 1 is a smoke-like type of loosely standing property at start-up, and a known technique for changing the duty ratio of pulses is employed.

The reciprocating motion of the electromagnetic plunger 15 is transmitted to the piston 21 and the leaky Sophie 38 to reciprocate in the cylinder 24 and the leak cylinder 39. When the piston 21 is reciprocated, i.e., displaced downward, the volume of the pump chamber 27 expands and becomes negative pressure, thereby opening the suction valve 28 and sucking the fluid in the suction hole 30.

Thus, when displaced upward, the volume of the pump chamber 27 is reduced and thus becomes a compression pressure (static pressure) to open the discharge valve 29 to discharge the fluid into the electromagnetic plunger operating chamber 19.

In addition, the piston 21 synchronously reciprocates the leaky Sophie 38 so that the volume change of the leak space 40 occurs, but there is no suction valve or discharge valve, and no pumping action.

The fluid discharged from the discharge valve and flowed into the electromagnetic plunger operating chamber 19 is discharged through the solenoid valve 60 smoothed by the accumulator 47 and opened by adjusting to a predetermined pressure in the relief valve 41. 62) is sent to the external device.

When the application of the pulse current to the electromagnetic coil is blocked, the reciprocating motion of the electromagnetic plunger, the piston 21 and the leaky Sophie 38 is stopped, and the solenoid valve 60 is seated on the toilet seat and the discharge hole 62 is closed. That is, a fluid of high pressure (for example, 7 kg / cm 2) is closed in the electromagnetic plunger operating chamber 19 downstream from the suction valve 28, which is inside the pump, and to the solenoid valve 60. This high pressure fluid passes between the piston 21 and the cylinder 24 and reaches the pump chamber 27 where it flows through the leak chamber 40 and the leak cylinder 39 in the leak space 40. It can flow out to the suction side and internal pressure can flow out to the suction side. That is, in the piston 21, the cylinder 24, the leaky Sophie 38, and the leak cylinder 39 which are the leakage paths, the piston 21 and the lease Sophiestone 38 are movable members, and dust is attached. Difficult automatic cleaning action is performed to increase the reliability.

The outflow time is about 2 to 3 seconds, and the gap between the piston 21, the cylinder 24, the leaky physique 38 and the leak cylinder 39, or the length of the cylinder 24 and the leaky Sophie 38 is determined. It can be controlled by adjusting. Therefore, when the internal pressure decreases in about 2 to 3 seconds after the pump stops and the pump is driven again, the discharge pressure changes the duty ratio of the pulse current applied to the electromagnetic coil (2) and rises loosely to reach the normal pressure. Can contribute to completeness.

Although an example is shown in which the shutoff valve is a solenoid valve 60 that is opened and closed by the magnetic attraction force of the magnetic rod 8, it has a solenoid coil for an independent solenoid valve, or a laboratory No. 61-21583, a laboratory No. 61-14635. The technique shown in the publication may be a valve that opens and closes with a change in the position of the electromagnetic plunger at the time of pump stop.

In FIG. 3, unlike the above-mentioned embodiment, the mechanical pressure rise time adjusting device 64 for softening is shown. The pressure rise time adjusting device 64 includes a cylinder for pressure rise time adjustment (hereinafter referred to as a pressure tank cylinder) 66 inserted into the forming hole 65 in the pump main body 10 and the inside of the pressure tank cylinder 66. And a spring 68 for pressing the sliding forging piston 67 and the forging piston 67. The forging cylinder 66 has a partition 69 at its inner center, and the front chamber 70a and the front and rear, respectively. The rear chamber 70b is formed. The through hole 71 is drilled through the partition 69 to communicate the two chambers 70a and 70b.

The filter 72 is accommodated in the front chamber 70a and communicates with the downstream side of the discharge valve 29 via the communication hole 73 in the forming hole 74 in the cylinder for pressure vessel 66. In addition, the rear chamber 70b is arranged such that the pressure piston piston 67 is slidable and is urged as a spring 67, and the pressure piston piston 67 opposes the pressure downstream of the discharge valve. Denoted at 75 is a stopper capable of assigning a spacer for stroke adjustment. The pressure cylinder 66 and the filter 72 are attached to the pump body 10 by being attached as an attachment plate 36 to which the accumulator 47 is attached. The pressure vessel piston 67 is provided with a leak hole and the like.

The pressure rise time adjusting device 64 is supplied with a fluid downstream from the discharge valve 29, ie, a high pressure, through the communication hole 73 when the pump driving is started, and then enters the first chamber 70a and enters the through hole 71. The pressure is applied to the pressure piston (67) through the through. When the pressure vessel piston 67 reaches a predetermined pressure (2 to 3 kg / cm 2), it starts displacement and expands the volume, for example, when it rises to 5 to 6 kg / cm 2, it stops the expansion of the volume. It is to loosen the pressure. In the pressure rise time adjusting device 64 of this configuration, the gap between the piston 21 and the cylinder 24, the pump chamber 27, the leaky Sophie 38 and the leak cylinder 39 as described above at the time of stopping the pump drive. The internal pressure of the pump flows out through the gap between the pump and the pressure can be reduced to the atmospheric pressure in about 2 to 3 seconds, so the piston 67 is rotated by the spring 68 and actuated again when the pump is restarted. Since other parts are the same as the above-described embodiment, the same parts are denoted by the same reference numerals and description thereof will be omitted.

As described above, according to the invention described in Claim 1, the pressure (high pressure) in the pump can be driven to the suction side through the gap between the piston and the cylinder, the pump chamber, and the leaky piston and the leak cylinder. It can be reduced within a predetermined time.

In addition, since the leaky Sophiestone always slides inside the leak cylinder during pump operation, even if dust is temporarily attached, it can be removed by the self-cleaning action, so that there is no irrational point such as filling the scale.

In addition, according to the invention described in claim 2, a mechanical pressure rise time adjusting device is attached, which is an electronic pump that slows the pressure rise by changing the volume at the initial stage of pump operation, and the internal pressure of the pump at the time of stopping the clearance between the piston and the cylinder. It is possible to operate the pressure rise time adjusting device which is discharged from the gap between the pump chamber, the leak sophie stone and the leak cylinder. It is not necessary to drill through holes in the piston of this pressure rise time adjusting device.

Claims (2)

An electromagnetic plunger reciprocated by energizing an intermittent current to the electromagnetic coil, a piston reciprocating in the cylinder in conjunction with the electromagnetic plunger, a suction valve and discharge valve acting in cooperation with the piston, and a discharge hole when the electronic pump is stopped. In the solenoid pump equipped with a shut-off valve, a leaky Sophiestone is installed at the tip of the piston so that the leaky Sophiestone can be inserted into the leaky cylinder, and the leaky piston has one tip and a leaky cylinder. The leaking space of the electronic pump, characterized in that in communication with the intake valve upstream. The electromagnetic pump according to claim 1, wherein a pressure rise time adjusting device is attached.