KR20200016026A - Displacement pump for resisting to thrust force - Google Patents

Abstract

Disclosed is a volumetric pump bearing thrust force. The volumetric pump bearing thrust force includes: a motor with a motor shaft protruding from a groove formed on one side surface of a housing; a rotary spindle combined with the motor shaft inserted into a hole formed on one side surface, and rotated in accordance with the rotation of the motor shaft; a piston combined with the rotary spindle while having a rotation axis not in parallel with the rotation axis of the motor shaft, and reciprocated while being rotated in accordance with the rotation of the rotary spindle; and a buffer member inserted into the groove of the motor to be combined, combined with the motor shaft penetrating a through hole formed in the center, and including a bearing combined with one side opposite to the other side coming in contact with the groove of the motor. The rotary spindle can be combined with the motor shaft to enable one side surface of the rotary spindle to come in contact with the bearing combined with the buffer member.

Description

Displacement pump for resisting to thrust force

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a metering pump that withstands thrust force, and more particularly to a metering pump that withstands thrust pressure so that thrust pressure is not applied to the motor shaft even when the piston is in operation.

Metering pumps are pumps whose discharge amount does not change unless the rotational speed of the drive motor or the angle between the motor shaft and the piston shaft is changed. Such metering pumps are used in various industries (water treatment industry, automobile industry, electronics industry, etc.) that require metering of liquid.

Patent No. 10-1205869 (quantitative pump) is shown an example of the metering pump. The metering pump has an eccentric shaft which makes an eccentric rotation when the drive motor is operated. The eccentric shaft is connected to a connecting rod, and the connecting rod is connected to a piston. Therefore, when the drive motor is operated, the eccentric shaft makes the eccentric rotation, which is converted into the rotation of the piston and the linear reciprocating motion through the connecting rod.

An object of the present invention is to provide a metering pump that withstands thrust pressure such that thrust force is not applied to the motor shaft even when the piston is operated.

The metering pump that withstands the thrust pressure according to an embodiment of the present invention for achieving the above object, the motor shaft is protruded in the groove formed on one side of the housing, the motor shaft is inserted into the hole formed on one side Rotating spindles are coupled and rotates as the motor shaft rotates, Piston coupled to the rotary spindles having a rotation axis that is not parallel to the axis of rotation of the motor shaft and reciprocating while rotating as the rotary spindles rotate The shock absorbing member is inserted into and coupled to the body and the groove of the motor, and the motor shaft is coupled to the through hole formed at the center thereof, and the bearing is coupled to the other side of the side opposite to the one side contacting the groove of the motor. It can be provided. The rotary spindles may be coupled to the motor shaft such that one side of the rotary spindles contacts a bearing coupled to the shock absorbing member.

The cushioning member has a portion surrounding the motor shaft protruding from the other side to which the bearing is coupled, and the protruding portion is inserted into a through hole formed at the center of the bearing, and the rotating spins are formed on the one side of the bearing. A groove in which the protruding portion of the buffer member is inserted may be formed in a portion corresponding to the protruding portion of the buffer member.

The groove formed on one side of the motor is circular, the buffer member is a cylindrical shape having the through hole formed in the center, the auxiliary may be coupled to the grooves formed on the one side and the circumferential surface, respectively.

The metering pump capable of withstanding the thrust pressure may further include a lubricating oil injecting means for injecting lubricating oil into a portion where one side of the rotary spins is in contact with a bearing coupled to the buffer member.

The metering pump that withstands the thrust pressure, the cover is coupled to one side of the housing of the motor and surrounding the rotating spins and one side of the rotating spins and the bearing coupled to the bearing coupled to the shock absorbing member can inject lubricant. Lubricating oil injecting means may be further provided to be connected to one side surface of the rotating spindle and the bearing coupled to the buffer member in the through hole formed in the cover.

The body portion includes a coupling portion coupled to the rotary spindle using spherical bearings, the piston having a groove formed in an opposite direction of the coupling portion, and a position where the piston is inserted and corresponding to the groove formed in the piston. It may be provided with a cylinder which is formed with an inlet port through which the object is introduced and an outlet port through which the object is discharged.

The metering pump that withstands the thrust pressure may further include an angle adjusting means for adjusting the angle between the axis of rotation of the rotary spindle and the axis of the piston by moving the piston while the piston is coupled to the rotary spindle. .

The rotary spins include one side that is in contact with the bearing and is coupled to the motor shaft to be rotated by being coupled to the motor shaft and coupled to the motor shaft in a state spaced apart from the first rotor. The second rotating body may be provided.

The metering pump that withstands thrust force according to an embodiment of the present invention has an advantage that the thrust pressure is not applied to the motor shaft even when the piston is operated. When the rotation shaft of the motor shaft and the rotation shaft of the piston are not parallel, when the piston operates according to the operation of the motor, a large thrust pressure is transmitted to the motor shaft. In the present invention, a thrust is provided to the housing of the motor by using a shock absorbing member and a bearing. By only transmitting pressure, the thrust pressure is not transmitted to the motor shaft, thus preventing the motor from failing, maximizing the life of the motor, and discharging the metered amount, thereby maximizing the performance and efficiency of the pump.

BRIEF DESCRIPTION OF THE DRAWINGS In order to better understand the drawings cited in the detailed description of the invention, a brief description of each drawing is provided.
1 is a perspective view of a metering pump that withstands a thrust force according to an embodiment according to the spirit of the present invention.
2 is an exploded perspective view of the metering pump withstanding the thrust pressure of FIG.
3 is a cross-sectional view of the metering pump withstanding the thrust pressure of FIG.
4 is a cross-sectional view of a metering pump showing a case in which the piston of FIG. 3 rotates and reciprocates.
5 is a cross-sectional view of a metering pump withstanding thrust pressure according to another embodiment of the present invention.
6 is a cross-sectional view of the metering pump showing a case in which the piston of FIG. 5 rotates and reciprocates.

DETAILED DESCRIPTION In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings that illustrate preferred embodiments of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a perspective view of a metering pump 100 to withstand the thrust force (thrust force) according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the metering pump 100 to withstand the thrust pressure of FIG. to be. 3 is a cross-sectional view of the metering pump 100 that withstands the thrust pressure of Figure 1, Figure 4 is a cross-sectional view of the metering pump 100 showing a case in which the piston of Figure 3 rotates and reciprocates. In the present invention, the displacement pump refers to a pump that discharges a desired amount of liquid by securing a space in a cylinder as necessary by sucking a solution as much as the space in the cylinder and discharging the solution sucked in the space. it means.

1 to 4, the dosing pump 100 capable of withstanding thrust pressure may include a motor 110, a rotary spindle 120, a body 150, a buffer member 130, and a bearing 135. have. The motor 110 may protrude the motor shaft 115 into the groove 117 formed on one side of the housing. The groove 117 may have various shapes, and the shape of the groove 117 may correspond to the shape of the buffer member 130 because it is a space in which the buffer member 130 to be described later is inserted. 1 to 4 illustrate a case where the shock absorbing member 130 has a cylindrical shape, and illustrates a case where the groove 117 formed on one side of the housing of the motor 110 also has a cylindrical shape.

The rotary spindle 120 may be rotated by the motor shaft 115 being inserted into and fixed to the hole H1 formed on one side thereof, and the motor shaft 115 rotates. That is, the motor shaft 115 is inserted into the hole H1 formed in the rotational spindle 120 and then fixed to the rotational spindle 120, so that the entire rotational spindle 120 rotates as the motor shaft 115 rotates. It can rotate in the same direction as the rotation direction of (115).

The body part 150 may include a piston 157 and a cylinder 153. The piston 157 may be coupled to the rotary spindles 120 and have an axis that is not parallel to the axis of rotation of the motor shaft 115. For example, in FIG. 1, the axis of rotation of the motor shaft 115 is a-a ', the axis of rotation of the piston 157 is b-b', and the a-a 'and b-b' directions are not parallel to each other. And as the rotating spindle 120 rotates, the piston 157 may rotate and reciprocate. For example, the piston 157 may include a coupling portion 155 having a bent shape, and the coupling portion 155 may be coupled using the rotary spindle 120 and the spherical bearing 170. The piston 157 may have a groove 159 formed in an opposite direction of the coupling part 155. In addition, the cylinder 153 into which the piston 157 is inserted may have a suction port 310 in which the object is sucked and a discharge port through which the object is discharged at a position corresponding to a position where the groove 159 formed in the piston 157 is formed. 320 may be formed. Therefore, when the motor shaft 115 rotates, the rotary spindles 120 coupled to the motor shaft 115 rotate, and when the rotary spindles 120 rotate, the piston 157 rotates to reciprocate. For example, FIG. 3 illustrates a case in which an object flows into the cylinder 153 through the suction port 310 by rotating the motor shaft 115 in the first direction, and in the case of FIG. As the shaft 115 rotates in the second direction, the object introduced into the cylinder 153 is discharged through the outlet 320.

In such an operation, since the rotating shaft of the piston 157 and the rotating shaft of the motor shaft 115 are not parallel, when the piston 157 rotates and reciprocates, a strong thrust pressure is transmitted to the motor shaft 115. . For example, in FIG. 3, the thrust pressure may be a pressure applied in a left to right direction. If the amount of the incoming object and the discharged object is increased or the motor rotation speed is increased, the stronger thrust pressure acts on the motor shaft 115. In the case of the motor 110 in which the motor shaft 115 is designed to move, i.e., the motor designed to move in the aa 'direction in the embodiment of FIG. 1, there is a danger that the thrust pressure may be easily broken. have.

Accordingly, the present invention transmits the thrust pressure applied to the motor shaft 115 to the housing of the motor 110 as the piston 150 operates by using the shock absorbing member 130 and the bearing 135, and the motor shaft 115. It uses a structure that prevents it from being delivered.

The buffer member 130 may be inserted into and coupled to the groove 117 formed in one side of the housing of the motor 110. In addition, the shock absorbing member 130 is coupled while the motor shaft 115 penetrates through the through hole H2 formed in the center thereof, and the bearing 135 is formed on the other side surface opposite to the one surface contacting the groove 117 of the motor 110. ) May be combined. That is, one side of the shock absorbing member 130 may contact the groove 117 of the motor 110 and the bearing 135 may be coupled to the other side of the shock absorbing member 130 exposed to the outside. The bearing 135 may be a thrust bearing, but the present invention is not limited to this case, and the bearing 135 of the present invention may be another type of bearing if the same effect as described below can be obtained.

As described above, the shape of the buffer member 130 and the shape of the groove 117 may correspond. In addition, the height of the buffer member 130 inserted into the groove 117 may be equal to or greater than or less than the depth of the groove 117. That is, when the buffer member 130 is inserted into the groove 117, the position of the other side of the buffer member 130 may be the same position as the housing surface of the motor 110, the groove 117 is formed, The position of the other side of the buffer member 130 may be protruded or recessed than the housing surface of the motor 110.

The shock absorbing member may have a cylindrical shape in which a through hole H2 is formed at a center thereof, and grooves may be formed on the one side surface and the circumferential surface of the motor 110 in contact with the groove 117. An o-ring or other auxiliary may be coupled to a groove formed on one side of the buffer member, and an o-ring or other auxiliary may be coupled to a groove formed on the circumferential surface.

The rotary spindle 120 may be coupled to the motor shaft 115 such that one side thereof contacts the bearing 135 coupled to the shock absorbing member 130. That is, the rotary spindles 120 are coupled in a state in which one side is maximally moved in the direction of the motor 110 as shown in FIG. 3, so that one side of the rotary spindles 120 is coupled to the buffer member 130. (135). Rotating spindles 120 may have a single body as shown in the figure, it may be composed of a plurality of rotating bodies spaced apart from each other. For example, the rotary spindles 120 may be provided with a first rotating body and a second rotating body spaced apart from each other and coupled to the motor shaft 115. The first rotating body 120 may include one side surface in contact with the bearing 135 and may be coupled to the motor shaft 115 to rotate. The second rotating body may include a second rotating body coupled to the motor shaft to rotate and spaced apart from the first rotating body, and coupled to the body part 150.

The shock absorbing member 130 has a portion 133 surrounding the motor shaft 115 protruding from the other side to which the bearing 135 is coupled, and the protruding portion 133 is formed through the center of the bearing 135. It may be inserted into the hole H3. In addition, one side of the bearing 135 may be coupled to the protruding portion 133 of the buffer member 130 and a surface (non-protruding flat surface) 131 adjacent thereto. A groove 123 into which the protruding portion 133 of the buffer member is inserted may be formed at a portion corresponding to the protruding portion 133 of the buffer member 130 among one side of the rotary spindle 120. And the other side of the bearing 135 on the surface (non-protruding flat surface) 121 and the groove 123 is inserted into the protruding portion 133 of the buffer member 130 of one side of the rotary spindle 120 is inserted Sides may be joined while in contact. For example, the surface 121 in contact with the other side of the bearing 135 of the rotary spindle 120 may be a material resistant to wear, for example, stainless steel, stainless steel, and the like.

And the metering pump 100 to withstand the thrust pressure is moved between the rotating shaft of the rotary spindle 120 and the shaft of the piston 150 by moving the body 150 in a state in which the body 150 is coupled to the rotary spindle 120 It may further include an angle adjusting means 160 for adjusting the angle of the. Angle adjusting means 160 may be a means that can be fixed after moving the body portion 150 along the guide bar by using a gear as shown in Figure 1, the present invention is not limited to this case and rotate If the body portion 150 can be moved and fixed so as to adjust the angle between the axis of rotation of the spindle 120 and the axis of the body portion 150, other various methods can be used.

Although not shown in the drawing, the quantitative pump 100 to withstand the thrust pressure of FIGS. 1 to 4 may inject lubricating oil into a portion where one side of the rotating spindle 120 is in contact with the bearing 135 coupled to the buffer member 130. It may be further provided with a lubricating oil injection means. For example, a hose or the like is coupled to an outer surface of the housing in which the groove 117 of the motor 110 is formed, and the hose is coupled to one side of the rotary spindle 120 and the shock absorbing member 130 ( If the 135 is formed to extend to the contact portion, since the lubricant can be injected through the hose may be the lubricant injection means. An embodiment of the lubricating oil injection means will be described in more detail with reference to FIGS. 5 and 6.

FIG. 5 is a cross-sectional view of a metering pump 500 capable of withstanding thrust pressure according to another embodiment of the present invention, and FIG. 6 is a metering pump showing a case in which the piston of FIG. 500).

1 to 6, the metering pump 500 that withstands thrust pressure includes a motor 110, a rotary spindle 120, a piston 150, a buffer member 130, a bearing 135, and a cover 510. And lubricating oil injection means 550 may be provided. The dosing pump 500 that withstands thrust pressure according to the embodiment of FIGS. 5 and 6 includes a dosing pump 100 that withstands the thrust pressure of FIGS. 1 to 4 except for the cover 510 and the lubricant injection means 550. Since the same, the overlapping portions are replaced by the descriptions related to FIGS. 1 to 4.

The cover 510 may be coupled to one side of the housing of the motor 110 while surrounding the rotary spindles 120. That is, the rotating spindle 120 may be coupled to the motor shaft 115 in the cover 510 and may be coupled to the shock absorbing member 130 with the bearing 135 interposed therebetween.

Lubricating oil injection means 550 is a rotating spindle (120) in the through hole formed in the cover 510 so as to inject lubricating oil to the contact portion of the bearing 135 coupled to one side of the rotary spindle 120 and the buffer member 130 ( One side of the 120 and the bearing 135 coupled to the buffer member 130 may be connected to the contact portion. For example, the lubricant injection means 550 formed by a hose, a groove, a through hole, or the like is coupled to an outer surface of the housing in which the groove 117 of the motor 110 is formed, and the lubricant injection means 550 is a rotary spindle. One side of the 120 and the bearing 135 coupled to the buffer member 130 may be formed to extend to the contact portion. One end of the lubrication injection means 550 is connected to the through hole formed in the cover 510, so that the lubricant is injected into the lubricant when the lubricant is injected into the through hole of the cover 510 without removing the cover 510. One side of the rotary spindle 120 and the bearing 135 coupled to the shock absorbing member 130 through the means 550 may be transmitted to the contact portion. However, the lubricating oil injecting means 550 is not limited to the case shown in FIGS. 5 and 6, and the lubricating oil is a part in which one side of the rotating spindle 120 is in contact with the bearing 135 coupled to the shock absorbing member 130. If you can pass, you can use a variety of other methods.

As described above, optimal embodiments have been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (8)

A motor having a motor shaft protruding from a groove formed in one side of the housing;
Rotating spindles are coupled to the motor shaft is inserted into a hole formed on one side and rotates as the motor shaft rotates;
A body part including a piston having a rotating shaft that is not parallel to the rotating shaft of the motor shaft, the piston being reciprocated while rotating as the rotating spindle rotates; And
The shock absorbing member is inserted into the groove of the motor, coupled to the through hole formed at the center thereof, and the motor shaft penetrates through the motor shaft.
The rotary spins,
A pump fixed to the thrust pressure, characterized in that coupled to the motor shaft so that one side of the rotating spindle is in contact with the bearing coupled to the buffer member. The method of claim 1, wherein the buffer member,
A portion surrounding the motor shaft protrudes from the other side to which the bearing is coupled, and the protruding portion is inserted into a through hole formed in the center of the bearing.
The rotary spins,
Metering pump to withstand the thrust pressure, characterized in that the groove in which the protruding portion of the buffer member is inserted is formed in a portion corresponding to the protruding portion of the buffer member of the one side. The method of claim 1,
The groove formed on one side of the motor is circular,
The buffer member,
A cylindrical pump having a through hole formed in a center thereof, and having a thrust pressure, wherein an o-ring is coupled to a groove formed in the one side and the circumferential surface. The metering pump according to claim 1, wherein the metering pump withstands thrust pressure.
Metering pump to withstand thrust pressure, characterized in that it further comprises a lubricating oil injection means for injecting lubricating oil to a portion of the side of the rotating spindle and the bearing coupled to the buffer member. The metering pump according to claim 4, wherein the metering pump withstands the thrust pressure.
A cover coupled to one side of a housing of the motor while surrounding the rotary spins; And
From the through hole formed in the cover to the part where the bearing coupled to the shock absorbing member in contact with the one side of the rotary spin so as to inject lubricating oil to the contact portion of the bearing coupled to the shock absorbing member Metering pump to withstand the thrust pressure, characterized in that it further comprises a lubricating oil injection means. The method of claim 1, wherein the body portion,
The piston including a coupling part coupled to the rotary spindle using spherical bearings and having a groove formed in an opposite direction of the coupling part; And
And a cylinder having an inlet port through which the object is introduced and an outlet port through which the object is discharged, at a position corresponding to the groove in which the piston is inserted and formed in the piston. According to claim 1, The metering pump that withstands the thrust pressure,
Metering pump to withstand thrust pressure, characterized in that further comprising an angle adjusting means for adjusting the angle between the axis of rotation of the rotary spindle and the axis of the piston by moving the piston in a state coupled to the rotary spindle. The method of claim 1, wherein the rotary spins,
A first rotating body including one side that is in contact with the bearing and coupled to the motor shaft to rotate; And
Metering pump to withstand the thrust pressure characterized in that it comprises a second rotating body coupled to the motor shaft and rotated and coupled to the body portion spaced apart from the first rotating body.

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