KR940002071B1 - Automatically pressure-adjusting type electromagnetic pump with pressure rise time-adjusting mechanism - Google Patents

Abstract

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Description

Self-regulating pressure electronic pump with pressure rise time adjustment mechanism

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

2 is a cross-sectional view of the statue.

3 is a cross-sectional view of the pressure rise time adjusting mechanism.

4 is a cross-sectional view of the pressure adjusting mechanism.

5 is a plan explanatory view showing an embodiment of the present invention.

6 to 8 are cross-sectional views showing the operating state of the pressure rise time adjusting mechanism.

9 is a characteristic diagram of an electronic pump of the present invention having a pressure rise time adjusting mechanism.

10 is a characteristic diagram of the pressure of a pressure rise time regulating device employing a conventional safety valve.

11 is a pressure characteristic diagram of the present invention.

12 is a P-Q characteristic diagram of the pressure and flow characteristics of the present invention.

* Explanation of symbols for main parts of the drawings

2: electromagnetic coil 7: piston

9: pump chamber 10: suction valve

11: outlet valve 29: cylinder

39: plunger 42: high pressure side chamber

43: low pressure side chamber 50: main spring

53: orifice 54: first valve

60: second valve 66: pressure reducing valve

69: hydraulic plunger 70: other cylinder

72: chamber opposite the pressure reducing valve 76: return passage

The present invention relates to a solenoid valve used for oil feeding of a small boiler using, for example, a gun type oil burner.

The discharge pressure characteristics of this type of electric pump are required to speed up the discharge pressure to the ignition point in order to eliminate the noncombustible discharge oil, and near the ignition point to reduce the explosion sound by ignition. Is to slow the discharge pressure rise, to reduce the leakage from the normal pump in order to operate the electric pump with good efficiency, and to stop the preparation for the next ignition, ), And to maintain the discharge pressure of the electronic pump at normal conditions.

The present applicant has already filed in order to satisfy such a request, and this is known as Japanese Patent Laid-Open No. 59-7787 and Japanese Patent Laid-Open No. 62-14173. In such a conventional method, a plunger is inserted into a cylinder connected to the upstream side of the discharge valve and the upstream side of the intake valve so as to freely slip, and the inside of the cylinder is divided into a high pressure side chamber and a low pressure side chamber. A first valve which communicates the high pressure side chamber and the low pressure side chamber via an orifice formed in the plunger, and blocks the communication between the high pressure side chamber and the low pressure side chamber until the pressure in the high pressure side chamber rises and the plunger moves to a constant value; In addition, when the pressure in the high pressure side chamber rises, a second valve is provided to allow a slight leakage of liquid and to block communication between the high pressure side chamber and the low pressure side chamber.

In addition, a safety valve is provided in parallel with the cylinder for returning an excess flow rate higher than a predetermined set pressure from the discharge side to the suction side.

Therefore, when the electromagnetic pump is driven, the communication between the high pressure side chamber and the low pressure side chamber is first blocked by the first valve, so that the discharge pressure rapidly rises to a certain value, and then the first valve opens to open the high pressure side chamber and the low pressure side chamber. Since the communication is through, the rise of the discharge pressure is loosened and ignition occurs at this time.

Further, when the pressure of the high pressure side chamber rises, the discharge pressure rises to the preset pressure set by the safety valve since the high pressure side chamber and the low pressure side chamber allow the liquid to leak slightly close according to the second valve. Then, when the operation of the solenoid pump stops, the plunger is pressurized to the high pressure side chamber along the main spring, so that the plunger returns to its original position. It is supposed to be.

However, according to the above-described apparatus, once the discharge pressure reaches the normal pressure, the pump flows back to the pump suction side via the safety valve as an extra flow rate inside the pump as well as the flow rate discharged from the nozzle after the outside, and the discharge pressure. As the plunger pressurizes the second valve and there is an amount of leakage from the very small gap between the plunger and the second valve to the suction side through the plunger and the orifice, the piston stroke is constant even during normal operation. Large pulsations occurred in the discharge pressure, and even combustion pulsations became loud.

Therefore, in the present invention, in addition to the demand for the conventional discharge pressure increasing characteristic, the pressure rise time adjustment that can reduce the combustion pulsation noise as well as the vibration of the discharge pressure and the vibration or noise of the electric pump at the normal time can be reduced. An object of the present invention is to provide a self-adjusting pressure electronic pump having a mechanism.

The gist of the present invention is to change the volume of the pump chamber by reciprocating the piston according to the intermittent energization in the electromagnetic coil, and the liquid is transferred by the cooperation of the suction valve and the discharge valve due to the volume change of the pump chamber. A solenoid pump for feeding pressure through a valve, wherein the plunger is inserted into the cylinder so as to be freely slipped, and the cylinder is divided into a high pressure side chamber and a low pressure side chamber which connect the inside of the cylinder to the discharge side passage on the downstream side of the discharge valve. The low pressure side chamber is communicated through an orifice formed in the plunger, pressurizing the plunger to the high pressure side chamber according to the juice spring disposed in the low pressure side chamber, and the high pressure side chamber until the movement of the plunger due to the increase in the high pressure side chamber pressure exceeds a certain value. Of the plunger due to an increase in the pressure of the high pressure side chamber The passage on the pressure rise time adjusting device and the discharge side passage provided with a second valve restricting communication between the low pressure side chamber and the suction side passage when the maximum pressure reaches the maximum, and when the maximum pressure is established. A pressure reducing valve is provided to limit the flow rate through the valve, so that the pressure reducing valve is displaced according to the hydraulic pressure plunger to which the discharge side pressure is applied. The hydraulic pressure plunger is a different cylinder installed separately from the cylinder. It is provided so that a slip is free in the inside, and an adjustment pressure spring is provided in the chamber on the opposite side of the pressure reducing valve, and a return passage communicating with the suction side passage of the electromagnetic pump in the chamber on the opposite side of the pressure reducing valve. It consists of a pressure regulating mechanism and the like.

Accordingly, as the electromagnetic pump is driven to increase the discharge pressure after the discharge valve, the discharge pressure rapidly rises because communication between the high pressure side chamber and the low pressure side chamber of the pressure rise time adjusting device is blocked by the first valve, and then the predetermined pressure is increased. When the plunger moves to the value, the first valve opens, the high pressure side chamber and the low pressure side chamber communicate with each other via the orifice, and then the rise of the discharge pressure is loosened. Then, when the plunger moves to the maximum, the low pressure side chamber according to the second valve The communication between the intake passage and the intake passage is narrowed to increase the discharge pressure to the set pressure set by the adjustment pressure mechanism including the pressure reducing valve installed in the discharge passage. In this case, the pressure reducing valve is displaced by the hydraulic plunger to which the set pressure is applied, and the limiting amount is adjusted compared to the flow rate corresponding to the set pressure flow rate, so that the stroke of the piston also ends in an amount sufficient to obtain the required set pressure.

Furthermore, since the discharge pressure which is higher than the set pressure is applied to the pressure rise time adjusting device, the amount of leakage from the pressure rise time adjusting device can be reduced and eliminated as compared with the conventional example.

Next, embodiments of the present invention will be described with reference to the drawings.

In FIGS. 1 to 4, the actual electronic pump 1 in the present invention is shown, and in FIG. 5, the electronic pump 1 described above for clarifying the connection state of each component. In the drawing, the electron pump 1 has an upper support spring 4 and a lower support supported by an electromagnetic plunger 3 which reciprocates according to the intermittent electromagnetic force of the electromagnetic coil 2. It is held in the electromagnetic plunger operating chamber 6 according to the spring 5 or the like.

And below the electromagnetic plunger 3, the piston 7 is integrally connected with the electromagnetic plunger 3 and fitted in the cylinder 8, and the pump chamber 9 has a volume according to the reciprocating motion of the piston 7 described above. In turn, the pump functions in cooperation with the intake valve 10 and the discharge valve 11.

That is, the liquid (for example, petroleum) sucked into the pump chamber 9 from the suction hole 12 via the suction valve 10 becomes discharge pressure of, for example, 10 kg / cm 2 from the discharge valve 11, and discharges. The electronic plunger operating chamber 6 provided with the accumulator 20 is adjusted through the side passage 44 to the pressure rise time adjusting mechanism 65 to be described below, and is adjusted to the set pressure by the pressure adjusting mechanism 65. It flows out and further reaches the solenoid valve 16 from the hole 13 formed in the electromagnetic plunger 3, and the hole 15 formed in the stator magnetic load 14, and the electromagnetic coil ( 2) is discharged from the discharge hole 18 formed in the discharge joint 17 via the solenoid valve 16 which was attracted by 2) and opened against the spring 16a.

The pressure rise time adjustment mechanism 23 controls the pressure increase characteristic as shown in FIG. 9 as shown in FIG. 2, FIG. 3, and FIG. 5 to FIG. It has a body portion (25) integrally with the body portion 25, one end of the body portion 25 is opened, one end of the body portion 25 is closed with a lid 26, the lid 26 ) Is screwed to the body portion 25 with a bolt 27.

The cylinder 29 was inserted into the body portion 25, and the left end of the cylinder 29 abuts on the inner surface of the lid 26, and the outer circumferential surface of the cylinder 29 and the body portion 25 O-rings 30 and 31 are interposed between the inner circumferential surfaces of

Moreover, the valve case 33 is inserted through the O-ring 38 in the recessed part 32 formed in the left end of the cylinder 29. As shown in FIG.

The valve case 33 has a base portion 33a having a diameter equal to the diameter of the recess portion 32, a convex portion 33b having a diameter smaller than the recess portion, and the like. As in 29, the lid 26 is brought into contact with the lid 26, and the right end of the convex portion 33b is abutted against and fixed to the bottom 34 formed in the middle of the cylinder 29. Surrounded by the cylinder 29, the annular space 35 is formed inside the convex portion 33b and the bottom portion 34, and the valve storage chamber 55 is formed, respectively.

On the other hand, on the outer circumferential surface and bottom portion 34 of the cylinder 29, a plurality of through holes 36 and 37 facing the annular space 35 described above are formed in the circumferential direction, respectively.

The plunger 39 is inserted in the cylinder 29 via O-rings 40 and 41 so as to be free of slip. The plunger 39 allows the cylinder 29 to have a high pressure side chamber 42 and a low pressure side chamber. It is divided into 43.

The high pressure side chamber 42 communicates with the discharge side passage 44 connected to the downstream side rather than the discharge valve 11 mentioned above via the annular space 35 and through-holes 36 and 37 mentioned above.

Moreover, the low pressure side chamber 43 communicates with the suction side passage 46 connected to the upstream side rather than the above-mentioned suction valve 10 via the communication groove 45 formed in the right end of the cylinder 29. As shown in FIG.

The plunger 39 is formed by fitting an orifice nozzle body 48 into a cylindrical plunger body 47 via an O-ring, and between the orifice nozzle body 48 and the body portion 25 described above. It is pressurized to the high pressure side chamber 42 by the elastically mounted juice spring 50.

In the plunger 39, a communication hole 51 is arranged between the plunger main body 47 and the orifice nozzle main body 48 in the axial center axis direction thereof, and at the same time the orifice nozzle main body 48 is disposed. An orifice 53 is formed.

The 1st valve 54 is provided in the valve storage chamber 55 formed in the convex part 33b of the valve case 33 mentioned above. The first valve 54 has a valve body 56 and a pressure spring 57 for urging the valve body 56 to the bottom 43 side. The valve body 56 has a plunger 39 by a predetermined value. The plunger 39 protrudes from the center hole 58 formed in the center of the bottom 34 of the cylinder 29 until the valve body 56 is brought into contact with the bottom 34 of the cylinder 29. The end of the communication hole 51 which abuts on the formed valve seat 59 and extends to the valve seat 59 is closed.

The second valve 60 is located in the low pressure side chamber 43, and is formed between the plunger 39 and the body portion 25, and the movable sheet portion 61 is formed near the right end circumference of the plunger 39. At the same time, the stationary sheet portion 62 is provided on the body portion 25 side opposite to the movable sheet portion 61.

The fixing sheet portion 62 is composed of a ring-shaped packing made of a soft material such as rubber or plastic, and is fixed to an end formed in the body portion 25.

Reference numeral 65 is a pressure regulating mechanism provided on the discharge side passage 63 described above. The pressure adjusting mechanism is adjusted to the set pressure as shown in FIGS. 2, 4, and 5, and the pressure reducing valve 66 is provided in the passage 63. ) Is disposed, the area of the flow path is appropriately reduced as the pressure reducing valve 66 and the throttling hole 67 to control the flow rate of the flowing fluid.

The pressure reducing valve 66 is in contact with the hydraulic plunger 69 which is a hydraulic mechanism via the rod 68, and is moved by the displacement of the hydraulic plunger 69.

The hydraulic plunger 69 is fitted in the other cylinder 70 provided in parallel with the cylinder 29 with respect to the intake valve 10 and the discharge valve 11 so that slip may be carried out freely.

Between these, an elastic member 71 such as an O-ring provided in the hydraulic plunger 69 is interposed so as to effectively absorb small pulsations generated by the hydraulic plunger 69 along with the elastic elastic member 71.

The adjustment pressure spring 73 is accommodated in the chamber 72 opposite the pressure reducing valve with the plunger 69 of the cylinder 70 interposed therebetween, and the pressure plunger 69 is pressed toward the pressure reducing valve side by the adjustment pressure spring 73. At the time of stopping the pump, the pressure reducing valve 66 moves to the leftmost side against the spring 74 having a small load, and the opening of the throttle hole 67 is the maximum.

Reference numeral 75 denotes a pressure adjusting screw, and by rotating this, the set force of the spring can be adjusted and the discharge pressure can be adjusted.

The return passage 76 opens one end in the chamber 72 opposite the pressure reducing valve of the cylinder 70 and opens the other end to the suction side of the electromagnetic pump.

Therefore, even if fluid leaks into the chamber 72 on the opposite side of the pressure reducing valve of the cylinder 70, it is often returned to the suction side via the return passage 76 according to the load on the suction side.

In the above-described configuration, when a pulse is supplied to the electromagnetic coil 2, it is excited to attract and displace the electromagnetic plunger 3 against the upper support spring 4, thereby discharging the electron plunger 3 to energy. Accumulate. When the supply of the pulse disappears, the electromagnetic coil 2 becomes unexcited and returns without reversing the upper support spring 4. Then, when the pulse is supplied again, as described above, the electromagnetic plunger 3 reciprocates the displacement repeatedly by resisting the upper support spring 4.

Accordingly, since the piston 7 also reciprocates, the liquid sucked through the intake valve 10 from the inlet 12 by pumping according to the intake valve 10 and the discharge valve 11 is the piston 7. Pressurized to be discharged through the discharge valve (11).

The pressurized liquid is respectively guided from the discharge side passage 63 to the pressure adjusting mechanism 65 including the pressure reducing valve 66, and the discharge side load (the apparatus for discharging the pressure rising time adjusting device 23). High pressure side chamber 42 communicating with the discharge side via the pressure reducing valve 66 as the discharge pressure (pressure between the discharge valve 11 and the pressure reducing valve 66) rises according to the nozzle of the nozzle. ) Also increases the pressure.

As a result, the left end surface of the plunger 39 is pressed to move the plunger 39 to the right against the juice spring 50 from the state shown in FIG.

In this case, since the valve body 56 of the first valve 54 is pressed by the inerting force of the pressure spring 57 and attached to the valve seat 59 of the plunger 39, the high pressure side chamber 42 and As the communication between the low pressure side chamber 43 is blocked, the leakage of the liquid is prevented, and the discharge pressure rapidly rises as shown in FIG. 9 because the pump capacity is consumed only for the discharge of the liquid and the movement of the plunger 39.

When the plunger 39 further moves, the valve body 56 of the first valve 54 abuts against the bottom 34 of the cylinder 29 as shown in FIG. This is the P ₁ point shown in FIG.

Then, as shown in FIG. 7, the valve seat 59 of the plunger 39 is separated from the valve body 56 of the first valve 54, so that the first valve 54 is opened to open the high pressure side chamber 42. And the low pressure side chamber 43 communicate with each other via the communication hole 51.

For this reason, the liquid in the high pressure cheuksil 42 at a rate determined by the diameter of the orifice 53 is exposed to low pressure cheuksil 43 decreases the rise rate of the discharge pressure (P), t ₂ time is in such a state ( For example, when 1 second has elapsed, the ignition point P ₂ is reached to ignite, and the discharge pressure at this time is, for example, 3.5 kg / cm 2.

Since the rising speed of the discharge pressure at this ignition point is loose, explosive ignition is prevented and it ignites quietly.

Further, when the pressure of the high pressure side chamber 42 rises, as shown in FIG. 8, the movable sheet portion 61 of the plunger 39 abuts against the fixed sheet portion 62 on the body portion 25 side. The second valve 40 is about to close. This is P ₃ point shown in FIG. 9, and after this P ₃ point, discharge pressure rises rapidly again. However, the low pressure side chamber 43 is sealed when the movable sheet part 61 is in close contact with the fixed sheet part 62 from the point P ₃ to the normal pressure (set pressure P ₄ ). The pressure of the side chamber 43 is equal to the pressure of the high pressure side chamber 42, and the force received from both sides of the plunger 39 is approximately equal (the movable sheet portion 61 is formed near the circumference, so that both sides of the plunger 39 are formed). Since there is not much difference in the pressure-receiving area of the plunger, the plunger 39 tries to move leftward in accordance with the return force of the juice spring 50.

Then, this time, the low pressure side chamber 43 communicates with the suction side passage 46, and the pressure of the low pressure side chamber 43 decreases, and the movable sheet part 61 of the plunger 39 is again fixed sheet part 62. Make contact with This is the case seen microscopically, and in practice, the plunger is restrained so that the movable sheet portion 61 is slightly away from the fixed sheet portion 62, and some liquid is removed from the gap between the movable sheet portion 61 and the fixed sheet portion 62. The suction side passage 46 is leaked.

When the discharge pressure reaches P ₄ after passing P ₂ , the pressure reducing valve 66 in the fully opened state shifts in the closing direction following the movement of the hydraulic pressure plunger 69 against the adjustment pressure spring 73. Done.

When the set pressure (P ₄ point) is reached, the open area of the throttle hole 67 is selected so that the amount corresponding to the discharge amount from the discharge hole 18 is supplied to maintain the set pressure.

The electromagnetic pump 1 discharges the fluid of the set pressure from the discharge port 18 in this manner, or the nozzle and pump inside (through holes 44 and downstream from the discharge valve 11, depending on the fluid resistance of the nozzle or the like). 63), when the pressure between the high pressure side including the plunger operating chamber 6, etc. increases, the hydraulic plunger 69 is displaced against the adjustment pressure spring 73, and the displacement amount is set via the rod 68. It is transmitted to the pressure reducing valve 66 and moved in the direction forcing the throttling action to the pressure reducing valve 66 to supply the flow rate to the restriction nozzle side through the throttle hole 67 and the pressure reducing valve 66. With this limitation, the discharge pressure is automatically adjusted to the set pressure.

Furthermore, if the pressure reducing valve 66 is throttled, the pressure in the discharge side passage 63 downstream from the discharge valve 11 increases, resulting in a decrease in the flow rate supplied through the discharge valve 11. As the pressure in the pump chamber 9 rises, the rise of the pressure appears as an increase in resistance to the upper support spring 4 of the electron plunger 3. For this reason, since the return stroke amount of the electromagnetic plunger 1 is reduced, the displacement (stroke) amount of the piston 7 is reduced, the amount of work is also reduced, and the amount of work and discharge is reduced.

On the contrary, if the pressure between the discharge port 18 and the plunger operating chamber 6 drops, the balance with the adjustment pressure spring 73 for pressurizing the old pressure plunger 69 is broken and the hydraulic pressure is applied to the adjustment pressure spring 73. In order to pressurize the plunger 69 and to move the pressure reducing valve 66 in the direction of loosening the throttling action to increase the passage flow rate, the pump chamber 9 as a result of the increase in the flow rate supplied via the discharge valve 11 increases. The pressure in the cylinder) decreases, and the stroke below the piston 7 by the upper support spring 4 increases. For this reason, from the fact that the amount of work increases and the pressure increases, the discharge pressure is automatically adjusted to the set pressure (for example, 7 kg / cm 2).

Thus, the stroke of the piston is determined relative to the discharge amount (the amount of work), so that the fermentation is minimal and can contribute to reducing the pulsation of the discharge pressure, the vibration of the pump itself, and the vibration sound at the normal time.

Furthermore, the stroke amount of the pump is very small at a certain pressure or less when compared with FIG. 10 of the characteristic diagram resulting from adopting the characteristics of the present invention as a synchro range, and FIG. 11 of the characteristic diagram provided with a conventional relief valve. The pulsation is decreasing.

In addition, since the pressure to the pressure rise time adjusting mechanism 23 described above is the discharge pressure (downstream input of the discharge valve 11), it is not regulated by the pressure reducing valve, so a high value of about 3 to 4 kg / cm 2 of the set pressure is achieved. Since it is caught by the plunger 32, it is possible to reduce the amount of minute leakage Δq leaking to the suction side of the pressure rise time adjusting mechanism.

Explaining this fact on the basis of Fig. 12, the total piston displacement of the solenoid pump having the pressure rise time adjusting mechanism using the relief valve is expressed as [1],

Q = Q ₇ + Q _R = q ₇ ... … … … … … … … … … … … … (One)

In this invention, it becomes like [2].

Q = Q ₇ + q ₁₀ ... … … … … … … … … … … … … … … (2)

Q ₇ is a discharge amount from the discharge hole 18, and Q _R is a leakage amount of liters, which is usually 1.5 to 2 times Q ₇ and q ₇ > q ₁₀ .

From the above facts, the Q _{R component} is completely eliminated in the characteristics of the present invention, which also reduces the movable stroke of the piston.

To expand the ratio of the diameter (D ₁₎ on the side facing the D ₂ and a low-pressure cheuksil 43 of the side that faces the high-pressure cheuksil 42 of the plunger 39 in the aforementioned pressure Fourth time adjustment mechanism 23 That is, if the pressure-receiving area ratio can be enlarged, it is also possible to set the amount of small leakage Δq to "0".

In this case, as indicated by the small leakage amount Δq 'line (Fig. 12), the leakage amount must be determined between 7 kg / cm 2 and 10 kg / cm 2.

This is because when the supply of electric power to the solenoid pump is stopped, the piston 7 is also stopped, the solenoid valve 16 is closed, and the pressure reducing valve 66 is moved in the direction of opening from the decrease in the internal pressure, and the pressure rise time adjusting mechanism This is because the pressure of the high pressure side chamber 42 of 23 drops rapidly to about 7 kg / cm 2, but in this case, the return force by the pressure spring 50 for pressing the plunger 39 must be surpassed.

By doing in this way, the plunger 39 is returned at the time of pump stop, and can cope at the time of restarting.

The discharge pressure was adjusted by rotating the pressure adjusting screw 75. Accordingly, the discharge pressure can be adjusted to a predetermined set pressure, but within the maximum capacity of the electromagnetic pump, that is, within the maximum discharge pressure in each nozzle. Needless to say, it should be a pressure range.

In the present invention, since the elastic member 71 is interposed between the hydraulic plunger 69 and the cylinder 70 by a 0-ring or the like, almost no fluid leaks into the chamber 72 opposite the pressure reducing valve. The hydraulic plunger 69 may be freely slipped into the cylinder 70 without installing the member.

As described above, according to the present invention, the increase characteristic of the discharge pressure at the initial stage of the pump startup is rapidly increased to near the ignition point, and the loose pressure rises before and after the ignition point to reduce the outflow of the non-combustible discharge oil and the like. In addition to this, the pressure control with pressure reducing valve installed in the middle of the discharge side passage allows the piston to move at the minimum stroke amount necessary to meet the required discharge (spray volume). The pulsation of the pressure could be reduced, and the vibration and noise of the electronic pump itself and the combustion noise could be reduced.

In addition, since the discharge pressure higher than the actual pressure of the pump is applied to the pressure rise time adjusting mechanism during the normal operation (set pressure), the pressing force on the plunger can be increased to reduce the amount of minute leakage to a minimum.

Further, by adopting the pressure-receiving area ratio of both plungers 39 large, the leakage amount can be set to "0" during the setting operation. Even by this, it can contribute to the reduction in piston stroke amount.

Claims (1)

The piston 7 is reciprocated in accordance with the intermittent energization of the electromagnetic coil 2 to change the volume of the pump chamber 9 so that the suction valve 10 and the discharge valve 11 are changed due to the volume change of the pump chamber 9. In the solenoid pump which pumps a liquid through a solenoid valve through the cooperative action of (), the plunger 39 is inserted in the cylinder 29 so that slippage is possible, and the inside of a cylinder is discharged | emitted rather than a discharge valve. The high pressure side chamber 42 and the low pressure side chamber 43 connected to the side passages are partitioned, and the high pressure side chamber 42 and the low pressure side chamber 43 communicate with each other via an orifice 53 formed in the plunger 39. (39) is pressed into the high pressure side chamber 42 according to the juice spring 50 disposed in the low pressure side chamber, and the high pressure side chamber until the movement of the plunger 39 due to the increase in the pressure of the high pressure side chamber 42 exceeds a predetermined value. At the same time as the first valve 54 for blocking the communication between the 42 and the low pressure side chamber 43, the pressure of the high pressure side chamber 42 is increased. Until the movement of the plunger 39 is maximized, the pressure rise time adjusting mechanism 23 provided with the second valve 60 for throttling communication between the low pressure side chamber 43 and the suction side passage 46, and discharge A pressure reducing valve 66 is provided on the side passage to throttle the flow rate flowing in the passage, and the pressure reducing valve 66 is displaced in accordance with the hydraulic plunger 69 to which the discharge side pressure is applied. 69) and the cylinder 29 are installed so as to be freely slipped in the other cylinder separately installed, and the adjustment pressure spring is arranged in the chamber 72 opposite the pressure reducing valve with the hydraulic plunger of the other cylinder interposed therebetween and And a pressure regulating mechanism (65) having a return passage (76) communicating with the suction side passage of the electromagnetic pump in the chamber (72).

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