KR20230166387A - metering pump - Google Patents

Abstract

The present invention has a minimal and simple structure and closes the suction and discharge when the piston reaches its peak within the cylinder chamber, thereby maintaining a constant amount of fluid within the cylinder chamber and maximizing the quantitative performance. The suction port and discharge port are on one side. A main body housing provided with a cylinder seal therein; A sealing whose outer diameter surface separates suction and discharge from the inner diameter surface of the cylinder chamber so that the sucked fluid is discharged while maintaining a certain curve while the upper portion is slidingly supported in the lifting space formed at the top of the cylinder chamber and connected to the cylinder chamber. A piston that rotates while maintaining a line at more than one point at all times; And a drive shaft mounted on the piston and rotatably provided on the main body housing including an eccentric cam to rotate it, wherein airtight members for airtightness are coupled to both sides of the portion in contact with the cylinder seal of the drive shaft. Provides a pump.
As a result, it not only simplifies manufacturing, but also reduces manufacturing costs. It also has the effect of minimizing the installation area due to the condition that the volume can be significantly reduced, as well as the effect of accurately supplying a fixed amount of fluid. also has

Description

Metering pump {metering pump}

The present invention relates to a metering pump. More specifically, it has a minimal and simple structure and maximizes metering performance by maintaining a constant quantity of fluid in the cylinder chamber by closing suction and discharge when the piston reaches its peak within the cylinder chamber. This is about a metering pump that makes it possible.

In general, a metering pump is a pump that does not change the rotation speed of the drive motor and does not change the discharge amount. It is widely used in various industrial fields to supply various chemicals or fluids quantitatively and precisely in chemical processes, water purification plants, wastewater and sewage treatment plants, and incinerators. It is used.

These metering pumps precisely inject a small amount of fluid at high pressure compared to centrifugal pumps, and are mainly manufactured with reciprocating cams and springs to easily obtain high pressure.

A metering pump uses the restoring force of a compressed spring in the stroke of sucking in fluid, and uses the power of an electric motor in the stroke of discharging fluid to obtain high pressure.

The prior art related to the various types of metering pumps described above is as follows.

First, as published in Republic of Korea Patent Publication No. 10-2016-0057082 (hereinafter referred to as 'Patent Document 1'), the structure for transmitting power to the piston is simplified and power is transmitted correctly according to the operating trajectory of the piston. A technology such as a piston-type metering pump structure, in which the corresponding Ottogi-shaped first and second pistons are rotated by the eccentrically rotating first and second power shafts in the Ottogi-shaped first and second cylinder spaces, has been proposed. there is.

In addition, as published in Republic of Korea Patent Publication No. 10-1784188 (hereinafter referred to as 'Patent Document 2'), a driving unit, a stroke control unit, an operating cam, and a rotating cam are provided so that the reciprocating movement of the plunger can be driven by a motor. Technologies such as a variable stroke metering pump including a power transmission unit, a pumping drive unit, and a pumping unit have also been proposed.

In addition, as published in Republic of Korea Patent Publication No. 10-1769787 (hereinafter referred to as 'Patent Document 3'), a non-eccentric metering pump including a rotating shaft, a piston rod, a means for changing the direction of movement, a piston head, and a lubricant injection path. A similar technology has also been proposed.

However, Patent Document 1 has the disadvantage of having a very complex structure, which not only requires a lot of manufacturing costs, but also has a large noise level when driven.

Patent Document 2 also has a fairly complex technical configuration, and has the disadvantage of increasing production costs and generating high noise during operation.

Patent Document 3 also has the disadvantage of having a complex technical configuration and requiring a large torque due to suction and discharge.

Republic of Korea Patent Publication No. 10-2016-0057082 Republic of Korea Patent Publication No. 10-1784188 Republic of Korea Patent Publication No. 10-1769787

The specific technical problem of the present invention to solve the above-described conventional problems is to have a simple minimum structure and close the suction and discharge when the piston reaches its peak within the cylinder chamber, thereby discharging the fluid within the cylinder chamber at a certain amount. The purpose is to provide a metering pump that can maintain and maximize metering performance.

Another specific technical problem of the present invention is to enable standardization of metering pumps by enabling variable production according to capacity.

Another specific technical problem of the present invention is to ensure excellent airtightness upon assembly.

The specific technical solution of the present invention for solving the above-described specific technical problem includes: a main body housing having a suction port and a discharge port on one side and a cylinder seal therein; A sealing whose outer diameter surface separates suction and discharge from the inner diameter surface of the cylinder chamber so that the sucked fluid is discharged while maintaining a certain curve while the upper portion is slidingly supported in the lifting space formed at the top of the cylinder chamber and connected to the cylinder chamber. A piston that rotates while maintaining a line at more than one point at all times; and a drive shaft mounted on the piston and rotatably provided on the main body housing, including an eccentric cam to rotate the drive shaft, wherein airtight members are coupled to both sides of the drive shaft in contact with the cylinder seal.

The cylinder seal to which the lifting space is connected has an eye bolt shape flipped 180°, and the piston also has an eye bolt shape flipped 180°, and a support rod to which a slider sliding in the lifting space is coupled is formed at the top. Includes.

The main housing includes an outer housing in which a suction port and a discharge port are formed, a cylinder housing in which a cylinder seal is formed including the lifting space on one surface of the outer housing, and an inner housing provided on one surface of the cylinder housing, The outer housing, the cylinder housing, and the inner housing are divided and formed to be coupled and fixed by a plurality of fastening members with at least one sealing member interposed therebetween, and the at least one sealing member is located between the outer housing, the cylinder housing, and the inner housing. It includes a first sealing member interposed on the surface for sealing in the direction of the drive shaft, and a second sealing member interposed between the outer housing, the cylinder housing, the inner housing, and the first sealing member for sealing in a direction perpendicular to the drive shaft. .

The cylinder housing includes at least two cylinder housings selectively disposed between the outer housing and the inner housing depending on the capacity.

It includes at least one sealing member interposed between the at least two cylinder housings, the outer housing, and the inner housing.

The present invention has a minimal and simple structure and closes suction and discharge when the piston reaches its peak within the cylinder chamber, thereby maintaining a constant quantity of fluid within the cylinder chamber to maximize quantitative performance, making it simple to manufacture. Of course, in addition to the effect of reducing production costs, the installation area can also be minimized due to the condition that the volume can be significantly reduced, and it also has the effect of enabling an accurate and quantitative supply of fluid.

In addition, it allows variable production according to capacity to realize standardization of metering pumps, providing convenience of use by selectively manufacturing depending on the intended use, and also has the effect of standardizing metering pumps according to variable capacity. .

In addition, by ensuring excellent airtightness upon assembly, it has the effect of securing high reliability of the product.

1 is a side cross-sectional view for explaining the present invention;
Figure 2 is a front cross-sectional view according to Figure 1;
Figure 3 is a front cross-sectional view for explaining the operating state of the piston of the present invention;
Figure 4 is a side cross-sectional view for explaining another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the attached drawings as follows, but the present invention is not limited or limited by the examples.

Figure 1 is a side cross-sectional view for explaining the present invention, Figure 2 is a front cross-sectional view according to Figure 1, and Figure 3 is a front cross-sectional view for explaining the operating state of the piston of the present invention.

As shown, metering pumps are widely used in various industrial fields to supply various chemicals or fluids quantitatively and precisely in chemical processes, water purification plants, wastewater/sewage treatment plants, incinerators, etc., as described in the technology behind the invention. .

These metering pumps precisely inject a small amount of fluid at high pressure compared to centrifugal pumps, and are mainly manufactured with reciprocating cams and springs to easily obtain high pressure.

A metering pump uses the restoring force of a compressed spring in the stroke of sucking in fluid, and uses the power of an electric motor in the stroke of discharging fluid to obtain high pressure.

However, as shown in Patent Documents 1 to 3, conventional metering pumps have the disadvantage of being quite complex in structure, and thus not only require a considerable amount of manufacturing cost, but also generate a lot of noise during operation.

Additionally, it has the disadvantage of requiring a large torque due to suction and discharge.

The present invention provides a metering pump that has a minimal and simple structure and maximizes quantitative performance by maintaining the fluid in the cylinder chamber at a constant constant volume by closing suction and discharge when the piston reaches its peak within the cylinder chamber. there is.

The metering pump (1) according to the present invention has a specific technical configuration including a main housing (10), a piston (20), and a drive shaft (30).

More specifically, the main body housing 10 is provided with a suction port 12 and a discharge port 14 on one side through which fluid is sucked and discharged, and a cylinder chamber 15 for suction and discharge is provided inside. has A lifting space 15A is formed in the upper part of the cylinder chamber 15 for the pivoting movement of the piston.

The unexplained symbol 100 is a pedestal.

The piston 20 suctions and discharges fluid into the cylinder chamber 15, and its upper portion slides within the lifting space 15A formed at the top of the cylinder chamber 15 to be connected to the cylinder chamber 15. It has a technical configuration in which the outer diameter surface rotates while maintaining a sealing line separating suction and discharge from the inner diameter surface of the cylinder chamber 15 at all times so that the sucked fluid is discharged while maintaining a certain curve. The cylinder seal and piston are in the form of a free curve made up of several arcs rather than a circle, and have the same shape as an eye bolt.

In other words, as the piston closes the suction and discharge of fluid at the peak in the cylinder chamber as shown in FIG. 2, that is, the upper shoulder portions of the piston come into close contact with both ends of the upper side of the cylinder chamber where the suction port and discharge port are formed. As it is closed, the fluid in the cylinder chamber maintains a constant quantity and has conditions to maximize the quantity. This happens instantaneously as the piston rotates within the cylinder chamber.

In addition, in the process of sucking and discharging fluid while the piston rotates as shown in Figures 3 (a) and (b), the outer diameter surface of the piston rotates while maintaining a single sealing line with the inner diameter surface of the cylinder seal, thereby reducing the inflow amount and It is possible to achieve excellent pumping efficiency as well as maximize quantitative performance with the same discharge amount.

The drive shaft 30 is connected to a power source to rotate the piston 20, and is rotatable on the main body housing 10, including an eccentric cam 32 to rotate the piston 20. It has a technical structure. A bearing (B) is interposed between the eccentric cam and the piston. The drive shaft is rotatable by bearings provided on both sides of the main housing.

In addition, airtight members 31 such as mechanical seals for airtightness are coupled to both sides of the portion of the drive shaft 30 in contact with the cylinder seal 15.

In addition, the cylinder chamber 15 to which the lifting space 15A is connected has an eye bolt shape reversed by 180°, and the piston 20 also has an outer diameter surface that is suction and inner diameter surface of the cylinder chamber 15. The shape of the eye bolt in the form of a cylinder seal (15) is flipped 180° so that the sealing line that separates the discharge always maintains at least one position and rotates, and a slider (22A) that slides in the lifting space (15A) is attached to the upper part. It includes forming a support rod 22 that is. At this time, when the piston is at its peak, the sealing points are formed at two points on both sides, that is, where the shoulder portions on both upper sides of the piston come into contact with both upper ends of the cylinder seal on the suction port and discharge port side as shown in FIG. 2. This allows the fluid in the cylinder chamber to maintain a constant, constant quantity at all times.

As the eccentric cam rotates eccentrically according to the rotation of the drive shaft, the piston also rotates around the support rod to which the slider inserted into the lifting space is coupled, sucking fluid through the suction port and then discharging it through the discharge port.

In other words, when the piston rotates inside the cylinder, the outer diameter surface of the piston rotates while the inner diameter surface of the cylinder chamber and the sealing line that separates suction and discharge are always maintained at more than one point, thereby ensuring suction and discharge with excellent quantitative performance. It repeats itself.

Therefore, the present invention does not have a complicated technical configuration, but has a simple technical configuration, as well as a sealing line that separates suction and discharge from the outer diameter surface of the piston to the inner diameter surface of the cylinder chamber so that the sucked fluid is discharged while maintaining a constant curve. By suctioning and discharging fluid through a rotating movement while maintaining the above-mentioned point, not only is manufacturing simple with a simple technical configuration rather than a complex technical configuration, but also the manufacturing cost can be reduced, and the volume can also be significantly reduced. As a result, the installation area can also be minimized.

In particular, there are conditions for maximizing reliability as a metering pump by maximizing the quantitative performance of the fluid.

Meanwhile, in the technical gist of the present invention, it provides a technical configuration that enables standardization of metering pumps by enabling assembly and variable manufacturing according to capacity as in other embodiments described later.

The main housing 10 includes an outer housing 10A in which the suction port 12 and the discharge port 14 are formed, and a cylinder chamber 15 including the lifting space 15A on one surface of the outer housing 10A. It includes a formed cylinder housing (10B) and an inner housing (10C) provided on one surface of the cylinder housing (10B), wherein the outer housing (10A), the cylinder housing (10B), and the inner housing (10C) include at least one or more It includes being divided and formed to be coupled and fixed by a plurality of fastening members 18 such as bolts and nuts with a sealing member 16 interposed therebetween.

In other words, the main housing of the present invention is provided with an outer housing and an inner housing on both sides based on the cylinder housing, so it not only has excellent disassembly and assembly, but also provides a condition for rapid replacement when a problem occurs in any part. have

In addition, by providing a plurality of cylinder housings according to capacity, it also provides the convenience of being able to easily manufacture from the minimum capacity to the maximum capacity without any inconvenience or inconvenience.

In addition, the at least one sealing member 16 due to the split formation of the main housing provides sealing in the direction of the drive shaft 30 on the surface between the outer housing 10A, the cylinder housing 10B, and the inner housing 10C. It is interposed between the first sealing member 16A, the outer housing 10A, the cylinder housing 10B, and the inner housing 10C and the first sealing member 16A in a direction perpendicular to the drive shaft 30. It includes a second sealing member 16B for sealing.

That is, by dividing the main housing of the present invention, the sealing in the direction of the drive shaft is performed by a first sealing member so that the fluid sucked and discharged does not leak or leak, and the sealing in the direction perpendicular to the direction of the drive shaft is performed by a second sealing member. By being double-sealed by the member, not only can the fluid be supplied accurately without disruption, but also the reliability of the product can be increased.

Therefore, the present invention does not have a complicated technical configuration, but can supply fluid in an accurate and fixed amount based on a simple technical principle, and also has excellent disassembly and assembly due to the split formation of the main body housing, and can be selectively applied according to capacity. It can also have high usability.

In addition, by double sealing the divided main body housing, leakage or leakage is fundamentally prevented, ensuring not only fixed quantity supply but also high reliability of the product.

Figure 4 is a side cross-sectional view for explaining another embodiment of the present invention.

As shown, in the above configuration, the metering pump of the present invention can be manufactured variably according to capacity, thereby providing a technical configuration that can realize standardization of the metering pump.

The cylinder housing (10B) includes at least two cylinder housings (10B) selectively disposed between the outer housing (10A) and the inner housing (10C) depending on the capacity. Each piston having the same structure as described above is provided on the drive shaft where each cylinder seal formed in each cylinder housing is located.

In the above, the operations within each piston and each cylinder chamber are the same as described above, so detailed description is omitted.

In addition, at least one or more sealing members 16 described above are interposed between the at least two cylinder housings 10B, the outer housing 10A, and the inner housing 10C. Since the at least one sealing member has the same structure and function as described above, a detailed description thereof will be omitted.

In other words, when only one cylinder housing is provided, the capacity is minimal, and the capacity can be increased by interposing a plurality of cylinder housings between the outer housing and the inner housing depending on the intended use.

As a result, not only can the capacity of the metering pump be selectively assembled and used depending on the intended use, but also the conditions for standardizing the metering pump can be established due to this technical configuration.

In addition, since fluid is supplied continuously by each piston driven in a plurality of cylinder housings, there is also the additional condition that no pulsation phenomenon occurs.

Accordingly, fluid supply can also be more stable and quiet.

1: Metering pump
10: main housing 10A: outer housing
10B: Cylinder housing 10C: Inner housing
12: suction port 14: discharge port
15: cylinder room 15A: lifting space
16: sealing member 16A: first sealing member
16B: second sealing member 18: fastening member
20: piston 22: support rod
22A: Slider 30: Drive shaft
31: airtight member 32: eccentric cam

Claims (5)

A main housing having a suction port and a discharge port on one side and a cylinder seal inside;
A sealing whose outer diameter surface separates suction and discharge from the inner diameter surface of the cylinder chamber so that the sucked fluid is discharged while maintaining a certain curve while the upper portion is slidingly supported in the lifting space formed at the top of the cylinder chamber and connected to the cylinder chamber. A piston that rotates while maintaining a line at more than one point at all times; and
It includes a drive shaft mounted on the piston and rotatably provided on the main body housing, including an eccentric cam to rotate the piston,
A metering pump including airtight members for airtightness coupled to both sides of the portion in contact with the cylinder seal of the drive shaft. According to paragraph 1,
The cylinder seal to which the lifting space is connected has an eye bolt shape flipped 180°, and the piston also has an eye bolt shape flipped 180°, and a support rod to which a slider sliding in the lifting space is coupled is formed at the top. Including metering pump. According to paragraph 1,
The main housing includes an outer housing in which a suction port and a discharge port are formed, a cylinder housing in which a cylinder seal is formed including the lifting space on one surface of the outer housing, and an inner housing provided on one surface of the cylinder housing, The outer housing, the cylinder housing, and the inner housing are divided and formed to be coupled and fixed by a plurality of fastening members with at least one sealing member interposed therebetween, and the at least one sealing member is located between the outer housing, the cylinder housing, and the inner housing. A first sealing member disposed on a surface for sealing in the direction of the drive shaft, and a second sealing member interposed between the outer housing, the cylinder housing, the inner housing, and the first sealing member for sealing in a direction perpendicular to the drive shaft. Metering pump. According to paragraph 3,
A metering pump including at least two cylinder housings selectively disposed between an outer housing and an inner housing depending on capacity. According to paragraph 4,
A metering pump comprising at least one sealing member interposed between the at least two cylinder housings, an outer housing, and an inner housing.

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