KR20170040760A - Pumping assembly - Google Patents

Abstract

The present invention relates to a pumping assembly for a high-pressure diesel pump, including a spring sheet member contacting a plunger return spring and a shoulder member coupled to a plunger, wherein the plunger is positioned by clearance fit through the spring sheet member, i.e., the plunger is separated from the spring sheet member, thereby not applying a spring force onto the plunger, such that the center of a vehicle body is set during an operation of the pump, wherein the assembly further includes a shoe, of which an upper surface is not vertical to a pumping shaft selectively. As such, the present invention is able to prevent abrasion of a plunger caused by a spring sheet and possibly relieve a resultant seizure.

Description

[0001] PUMPING ASSEMBLY [0002]

The present invention relates to a pumping assembly for a pump, and more particularly to a pumping assembly for a high pressure diesel fuel pump.

A currently known pumping assembly 2 is shown in Fig. 1, which includes a plunging element in the form of a plunger 4 and a plunger return spring 6 located within the spring chamber 8. Rotation of the cam lobe 80 of the drive shaft assembly causes force to be transmitted to the plunger 4 through the roller 14 and the shoe 12 to cause the plunger 4 to move in the reciprocating motion, .

The components that transmit the reciprocating motion of the cam lobe 80 to the plunger 4 must always be in contact with each other. The spring 6 maintains contact between the roller 14 and the cam lobe 80 by acting through the spring seat 10 rigidly mounted on the plunger 4. The secondary function of the spring seat 10 is to keep it concentric with the upper end of the spring 6, acting as a guide for the lower end of the spring 6.

Because spring force is transmitted through the spring seat 10 / plunger 4 assembly, it receives spring forces axially and radially during charging and pumping strokes.

The disadvantage of this prior art embodiment is that the radial spring force / side load applied to the plunger 4 through the contact between the spring seat 10 and the plunger 4 causes wear and possibly wear of the plunger 4 Can cause a resulting seizure.

It is an object of the present invention to provide a pumping assembly that at least mitigates the problems that occur in known embodiments.

According to the present invention, in a first aspect, there is provided a pumping assembly according to claim 1.

The pumping assembly may further include a shoulder member coupled to the plunger at or near a second end of the plunger,

Wherein the surface adjacent the end of the spring spaced from the housing portion is provided on a radial section of the spring seat member and the radial section of the spring seat member is located between the shoulder member and the housing portion,

The surface of the spring sheet member adjacent the shoe includes a surface of the axial section of the spring seat member and the shoulder member is positioned within the gap between the axial section of the spring seat member and the plunger.

In one embodiment, the upper surface of the shoe closest to the plunger and spaced from the roller is not perpendicular to the pumping axis.

The present invention will be described by way of example with reference to the accompanying drawings.
1 is a longitudinal section of a prior art pumping assembly,
2 is a longitudinal sectional view of a pumping assembly according to a first embodiment of the present invention,
Figure 3 is a partial cross-sectional view of the pumping assembly of Figure 2;
Figure 4 is a partial perspective sectional view of the pumping assembly of Figure 2,
5 is a longitudinal section of a pumping assembly according to a second embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described with reference to the orientation of the drawings. The terms top, bottom, top, bottom, top, bottom, horizontal and vertical are not intended to be limiting.

Referring to FIG. 2, the present invention includes a pumping assembly 102. The pumping assembly 102 includes a pumping element in the form of a plunger 104 and a spring 106 positioned within the spring chamber 108.

The plunger 104 is positioned such that its first, upper end 150 is located within the housing portion 190 and the second, lower end 152 is located closest to the shoe 112. The shoe 112 is positioned within the void 160 of the shoe guide 116.

The rotation of the cam lobe 180 of the drive shaft assembly causes the force to be transmitted to the plunger 104 through the roller 114 and the shoe 112. The transmitted force causes the plunger 104 to move in a reciprocating motion along the pumping axis A.

The spring 106 includes a first upper end 170 closest to the housing portion 190 and a second lower end 172 spaced from the housing portion 190 and closest to the shoe 112.

A spring sheet member 120 is positioned around the plunger 104. [ Also, a shoulder member 140 is positioned about the plunger 104 at or near the lower end 152 of the plunger 104.

3, the spring seat member 120 includes a radial section 122 spaced from the shoe 112 and extending radially relative to the pumping axis A, And an axial section (124) extending axially with respect to the pumping axis (A) between the shoe (112) and the shoe (112).

The axial section 124 extends from the connection point 136 with the radial section 122 toward the shoe 112 and there is a gap 126 between the axial section 124 and the plunger 104.

The radial section 122 has an upper surface 128 (i.e., a surface facing the housing portion 190) adjacent to the lower end 172 of the spring 106, so that the radial direction of the spring sheet member 120 The top surface 128 of the section 122 serves as a spring seat.

The spring seat member 120 is configured such that the lower surface 132 of the axial section 124 of the spring seat member 120 spaced from the housing portion 190 is spaced from the upper surface 132 of the shoe 112 spaced from the roller 114. [ Is positioned on the shoe (112) to be adjacent to the shoe (164).

The plunger 104 protrudes through the gap through hole 134 provided in the spring seat member 120. The plunger 104 is not engaged with the spring seat member 120 due to the clearance fit between the through hole 134 of the spring seat member and the plunger 104. [

The shoulder member 140 is coupled to the plunger 104, e.g., an interference fit, toward the lower end 152 of the plunger 104. The shoulder member 140 is positioned farther away from the housing portion 190 than the radial section 122 of the spring seat member 120 such that the radial section 122 of the spring seat member 120 is spaced from the housing portion 190 And the shoulder member 140, as shown in Fig.

At the time of the charging stroke of the pumping assembly 102, the spring force of the spring 106 acts on the spring seat member 120 and presses the spring seat member 120 downward. Adjacent the lower surface 130 of the radial section 122 of the spring seat member 120 relative to the upper surface 144 of the shoulder member 140 is the shoulder member 140 and therefore the shoulder member 140, Resulting in corresponding downward movement of the plunger 104 to which it is coupled.

Another optional feature of the invention is shown in Fig. In the embodiment of the pumping assembly 202, all other components are the same as in the first embodiment except for the shoe 212. The top surface 264 of the deformed shoe 212 spaced from the roller 114 is not at right angles to the pivoting axis A, i.e., (The angle setting of the surface 264 is highlighted in Fig. 5 for ease of illustration). As the spring force is amplified by the angle setting of the shoe upper surface 264 in this embodiment, side-loading on the shoe 212 during use of the pumping assembly 202 causes side loads ).

In the present invention, the spring force from the plunger return spring 106 is transmitted to the shoe 112 via the spring seat member 120. The spring sheet member 120 is not coupled to the plunger 104 as in the prior art embodiment. This is advantageous in that the spring seat member 120 adds a stabilizing action on the shoe 112, due to the radius of action of the spring force, thereby limiting the inclination of the shoe 122 and any resulting lateral loads.

Another advantage of the present invention is that the fluid film is re-established around the circumference of the plunger 104. During the pumping stroke, the plunger 104 will be forced to adopt the desired position / orientation by the pumping force and the plunger return spring force. If the size and orientation of the plunger return spring force is such that the plunger 104 maintains this position during the charge stroke, the bore of the housing 190 where the plunger is located at the contact position and the plunger 104 Lt; RTI ID = 0.0 > fluid < / RTI > In the case of the separate plunger 104 of the present invention, since no further spring force acts on the plunger 104 during the charge stroke, i.e., the plunger 104 is not constrained in the radial direction, Can be set to self-centering. Thus, the fluid can find the flow path between the plunger 104 and the bore.

Conventional technology
2: pumping assembly
4: plunger
6: Spring
8: Spring chamber
10: spring seat
12: Shoo
14: Roller
80: Cam Lobe
Invention
102, 212: pumping assembly
104: plunger
106: spring
108: Spring chamber
112: Shu
114: Roller
120: spring seat member
122: a radial section of the spring seat member
124: axial section of the spring seat member
126: Pore of the axial section
128: upper surface of the radial section
130: bottom surface of the radial section
132: Lower surface of the axial section
134: Clearance through hole of the spring sheet member
136: connecting point of the spring seat member
140; The shoulder member
150: a first, upper end
152: the second, lower upper end of the plunger
160: Air gap of the spring seat member
162, 264: shoe upper surface
170: upper end of the spring
172: Lower end of spring
180: Cam robe
190: housing part
A: Pumping axis

Claims (1)

A pumping assembly (102) comprising a plunger (104) and a spring (106) positioned within a spring chamber (108) wherein a first end (150) of the plunger (104) is located within a housing portion (190) The second end 152 of the plunger 104 spaced from the first end 150 is proximate to the shoe 112 and 212 and is reciprocated along the pumping axis A of the plunger 104, Movement is caused by forces transmitted from the rotatable cam lobe 180 through the roller 114 and the shoe 112 and 212 in the pumping assembly 102,
The pumping assembly 102 further includes a spring seat member 120 including a surface 128 abutting an end 172 of the spring 106 spaced from the housing portion 190, The member 120 further includes a surface 132 adjacent the shoe 112, 212,
The plunger 104 is located in the through hole 134 of the spring seat member 120 and a clearance fit exists between the through hole 134 of the spring seat member and the plunger 104 ,
The pumping assembly 102 further includes a shoulder member 140 coupled to the plunger 104 at or near a second end 152 of the plunger 104,
The surface 128 abutting the end portion 172 of the spring 106 spaced from the housing portion 190 is provided on the radial section 122 of the spring seat member 120, A radial section 122 of the member 120 is positioned between the shoulder member 140 and the housing section 190,
The surface 132 of the spring seat member 120 adjacent the shoe 112 and 212 includes a surface 130 of the axial section 124 of the spring seat member 120, 140 are positioned within the gap 126 between the axial section 124 of the spring seat member 120 and the plunger 104,
The shoe 212 includes an upper surface 264 proximate to and spaced from the plunger 104 and an upper surface 264 of the shoe 212 positioned on the pumping axis A Not perpendicular,
Pumping assembly.

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