JP4589623B2 - Metering pump - Google Patents

Description

  The present invention relates to a metering pump that fills a container with a highly flammable organic solvent such as alcohol or acetone, and more particularly to a metering pump that does not have a mechanical sliding portion therein.

  Conventionally, a metering pump capable of accurately delivering a certain amount of liquid has been provided. As the metering pump, various types of pumps such as a reciprocating type and a diaphragm type are used depending on the type and properties of the target liquid.

  Specifically, the reciprocating type such as a piston type has a structure in which a rod reciprocates in a cylinder. The reciprocating pump has a sliding portion and includes a seal member such as an O-ring.

  The diaphragm type has a structure in which a part of a pump chamber is formed by a diaphragm, and the volume of the pump chamber is increased or decreased by inflating or denting the diaphragm with a motor, hydraulic pressure, air pressure, or the like. The pump chamber is provided with a suction port for sucking fluid and a discharge port for discharging.

  In addition, a pump combining these has been developed. For example, JP-A-2001-182660 and JP-A-2001-193653 disclose metering pumps. These metering pumps are metering pumps that suck and discharge fluid discharged into the pressure chamber by reciprocating movement of the piston part. The piston part is connected to the first piston member and the second piston member via a retainer member. The discharge diaphragm and the pressure diaphragm are arranged to face each other on the retainer member side of the first piston member and the second piston member, and the folded portions of the mutual diaphragms are arranged to face outward. .

JP 2001-182660 A JP 2001-193653 A

  However, if there is a mechanical sliding part inside the reciprocating pump, it is usually necessary to apply a lubricant such as grease to that part to reduce friction and ensure smooth movement. However, when the target liquid is an organic solvent such as alcohol or acetone, such a lubricant is dissolved by the organic solvent and becomes useless. Therefore, a great frictional force acts on the sliding portion, and such a metering pump cannot be used at all.

  In the case of a pump that is movable by a motor, electricity, or the like, there is a risk of ignition by sparks or heating when the target liquid is a highly flammable organic solvent such as alcohol or acetone.

  Moreover, the volume of the fluid to be discharged is the same as the volume of the pump chamber, and there is a problem in that it cannot be matched with the container for storing the discharged fluid. Furthermore, there is a problem that the fluid in the discharged container cannot be set to a predetermined pressure.

  Accordingly, the present invention provides a metering pump that solves these problems and does not have a mechanical sliding portion when filling a container with a highly flammable organic solvent such as alcohol or acetone. Let it be an issue. Another object of the present invention is to provide a metering pump capable of safely filling a container with a highly flammable organic solvent such as alcohol or acetone without using power such as electricity or a motor. Furthermore, this invention makes it a subject to provide the metering pump which can be match | combined with the container which accommodates the discharged fluid, without restrict | limiting the capacity | capacitance of the fluid to discharge to the capacity | capacitance of a pump chamber.

In order to solve the above-mentioned problem, the invention according to claim 1 is a metering pump that sucks and discharges a predetermined amount of liquid , and includes an air inlet, an air passage opening, and an air outlet. The air discharge port includes an air inlet / outlet passage having a relatively larger diameter than the air passage port, and is decompressed through a suction path communicating with the air passage port by introducing pressurized air from the air inlet port. A pump body having a decompression chamber and a cylinder portion that is arranged to communicate with the decompression chamber and sucks the liquid, and discharges the sucked liquid to the outside from a discharge port provided in the pump body. A cylinder portion having a suction passage that is arranged, and the decompression chamber is evacuated by a buoyancy when a predetermined amount of liquid is sucked through the cylinder portion by decompressing the decompression chamber. Suction path A float portion for closing between, comprising a suction passage which is closed by the float unit, a decompression unit for the diaphragm portion is disposed on the upper side communicates with the air passage opening, is blocked by the float unit A decompression unit that is further decompressed than the decompression chamber , and the diaphragm unit is provided with an initial air introduction pipe provided so as to communicate with the air inlet and a pressurized air introduced through the initial air introduction pipe It is arranged so that it can be opened and closed with the air introduction pipe that guides the cylinder to the cylinder part, and is formed so that the pressurized air introduced through the initial air introduction pipe pressurizes the diaphragm part from the side opposite to the decompression part side When the liquid is sucked into the decompression chamber, the pressurized air is prevented from flowing into the air introduction pipe against the pressure of the pressurized air introduced through the initial air introduction pipe. By department Decompression unit is when it is further reduced pressure, characterized in that it is configured to introduce the air inlet pipe disposed an opening to the pressurized air to be in communication with the cylinder portion and the vacuum chamber by being blocked Te Provide metering pump.

  In order to solve the above-mentioned problem, the invention according to claim 2 is the metering pump according to claim 1, wherein the cylinder portion is provided with a suction port for sucking liquid, and a check valve is provided at the suction port. It is characterized by being.

In order to solve the above-mentioned problems, the invention according to claim 3 is the metering pump according to claim 1 or 2, wherein the float portion has a substantially spherical shape, and is an opening formed in a substantially circular shape formed in the suction path. It is characterized in that the air suction path of the decompression chamber is closed by sealing the part with its curved surface.

  In order to solve the above-mentioned problem, the invention according to claim 4 is the metering pump according to claim 3, wherein a packing member is disposed around the opening so as to be in close contact with the surface of the float part without any gap. It is characterized by being.

In order to solve the above-mentioned problems, the invention according to claim 5 is the metering pump according to any one of claims 1 to 4, wherein the diaphragm portion is provided via the initial air introduction pipe when the decompression chamber is decompressed. the decompression unit side by the compressed air introduced Te without opening against the pressure to pressurize the diaphragm portion from the opposite side, than the internal pressure of the inner pressure of the pressure reducing unit is at least reduced pressure chamber by the float portion closes the suction passage It is held by an elastic body so that it is opened by the pressure that pressurizes the diaphragm part from the opposite side to the decompression part side by the pressurized air introduced through the initial air introduction pipe when the pressure is low. It is characterized by.

In order to solve the above-mentioned problems, the invention according to claim 6 is the metering pump according to any one of claims 1 to 5, wherein the pump body is provided with a discharge port, and the discharge port has a predetermined value. A hose for filling liquid into the container can be attached, and the decompression chamber and the cylinder part are communicated with each other through a decompression pipe, and the decompression pipe is connected with an air introduction pipe through a valve. Although it does not open from the pressure reducing pipe side, it is formed to open from the air introduction pipe side, whereby the liquid sucked into the cylinder portion and pressurized air can be filled in the container. .

  According to the metering pump according to the present invention, since it does not have a mechanical sliding portion, the container can be easily filled even with a flammable organic solvent such as alcohol or acetone. is there.

  In addition, according to the metering pump according to the present invention, since it is moved by pressurized air instead of a motor or electricity, it can be safely performed without causing problems such as ignition to highly flammable organic solvents such as alcohol and acetone. There is an effect that the container can be filled.

  Hereinafter, the metering pump according to the present invention will be described in more detail based on the illustrated preferred embodiment. FIG. 1 is a schematic sectional view of an embodiment of a metering pump 1 according to the present invention.

The metering pump 1 includes a pump body 2 and a cylinder part 3.
First, the pump body 2 will be described.

  The pump body 2 includes a pump body upper body 2A, a pump body middle body 2B, a pump body lower body 2C, a bolt 2D, a float part 21, a packing member 22, a diaphragm part 23, an elastic body 24, A decompression chamber 25, an air inlet / outlet passage 26, an air passage pipe 27, and a discharge port 28 are provided.

  Between the pump main body upper body 2A and the pump main body middle body 2B, at least the diaphragm portion 23 and the elastic body 24 are accommodated. Further, at least the float portion 21 and the packing member 22 are accommodated between the pump main body middle body 2B and the pump main body lower body 2C. And these are united and united with the volt | bolt 2D. The reason for dividing into a plurality of parts is to provide a fluid passage such as the decompression chamber 25, the air inlet / outlet passage 26, the air passage pipe 27, and the discharge port 28, that is, for processing. Therefore, if these are provided, they may be integrally formed from one member from the beginning. Alternatively, if these are provided, they may be separately divided into a plurality of members and combined.

  The pump body upper body 2A, the pump body middle body 2B, the pump body lower body 2C, and the bolt 2D are all made of a steel material. However, the present invention does not exclude the production of an alloy such as an Al alloy or Mg alloy, ceramics, or synthetic resin. However, the metering pump according to the present invention is intended to be used for an organic solvent such as alcohol or acetone. It is therefore necessary to be made from materials that are inert with the organic solvent to be used.

  The float unit 21 is a sphere. In addition, the interior is hollow. The float unit 21 is made of plastics. However, the present invention only needs to have a substantially spherical shape. Further, the present invention may be made from other materials as long as it is made from a material having a density smaller than the density of the organic solvent to be used. Of course, even if it is a material which has a density larger than the density of the organic solvent which is the object to be used, it is sufficient that the float part 21 as a whole can float on the organic solvent.

  The packing member 22 is an O-ring. The packing member 22 is provided around the opening 25a of the decompression chamber 25, and is disposed for the purpose of closely adhering to the surface of the float portion 21 without a gap. Note that the present invention does not exclude the fact that the packing member 22 is not provided as long as the float portion 21 can be in close contact with the opening 25a of the decompression chamber 25 without a gap. Further, the present invention does not exclude the use of a member having elasticity other than the O-ring as the packing member. Further, the present invention does not exclude applying grease to the packing member 22. However, it is better not to use grease in consideration of contamination of organic solvents. However, even when grease is used, it must be inert with the organic solvent.

  The diaphragm unit 23 is a diaphragm. The diaphragm part 23 is made of rubber. However, the present invention does not exclude that the diaphragm 23 is made of an elastic material other than rubber. Specifically, it may be made of metal.

  The elastic body 24 is a spring. And it is metal. However, the present invention does not exclude elastic bodies other than springs, specifically rubber. Moreover, it does not exclude that it is synthetic resin properties, such as plastics other than metal.

  The decompression chamber 25 is a space that is decompressed by the pressurized air Air, as will be described later. It is also a space in which the float unit 21 is stored. The decompression chamber 25 includes a decompression part 25c such as a suction path 25b and decompression pipes 25d and 25e via the opening 25a. And the upper part of the pressure reduction part 25c is connected with the area | region in which the diaphragm part 23 and the elastic body 24 are located. Further, the decompression pipes 25 d and 25 e are connected to the cylinder part 3. Further, the decompression chamber 25 is connected to an air access path 26 shown below. The air passage pipe 27 is also connected through the cylinder portion 3 and the like.

  The air entrance / exit passage 26 is a passage for the pressurized air Air. The air access passage 26 includes an air inlet 26a, an air passage 26b, and an air outlet 26c. The pressurized air Air enters from the large-diameter air inlet 26a and reaches the small-diameter air passage 26b. The pressurized air Air that has come out of the air passage port 26b is discharged from an air discharge port 26c having a larger diameter than the air passage port 26b. However, the reason why the air inlet 26a and the air outlet 26c have a large diameter is in comparison with the air passage 26b.

  The air passage tube 27 is a passage for the pressurized air Air. The air passage tube 27 includes an initial air introduction tube 27a and air introduction tubes 27b, 27c, and 27d. The initial air introduction pipe 27a and the air introduction pipes 27b, 27c, and 27d are connected. The air passage tube 27 communicates with the decompression tube 25d and the air inlet 26a. A diaphragm portion 23 is located between the initial air introduction tube 27a and the air introduction tube 27b, and the passage is closed in a normal state. However, when the diaphragm 23 is pushed downward in the drawing, the path between the initial air introduction pipe 27a and the air introduction pipe 27b is connected.

  The discharge port 28 is connected to the suction passage 33 of the cylinder part 3. Then, a fluid such as an organic solvent can be discharged to the outside through the valve 29. The valve 29 is shown outside the pump main body 2 in the figure, but may be located inside the pump main body 2. It is also possible to connect to the external container 100 via the hose 101. Furthermore, the present invention does not exclude not providing the valve 29.

  Although not shown, a valve is provided between the decompression pipe 25d and the air introduction pipe 27d. This valve does not open from the decompression pipe 25d, but opens from the air introduction pipe 27d side. On the other hand, although not shown, the pressure reducing pipe 25e is provided with a valve. This valve opens from the cylinder portion 3 side, but does not open from the opposite side. However, the present invention does not exclude not providing these valves.

Next, the cylinder part 3 will be described.
The cylinder part 3 includes a suction port 31, a check valve 32 provided in the suction port 31, and a suction passage 33. And the cylinder part 3 is hollow inside. The cylinder part 3 is made from a steel material. However, the present invention does not exclude the production of an alloy such as an Al alloy or Mg alloy, ceramics, or synthetic resin. However, the metering pump 1 according to the present invention is intended to be used for an organic solvent such as alcohol or acetone. It is therefore necessary to be made from materials that are inert with the organic solvent to be used.

  The suction of the organic solvent from the suction port 31 is controlled by the check valve 32. All of the check valves 32 are not shown in the figure. In the drawing, only the ball that is a part of the check valve is shown as the check valve 32. As will be described later, the check valve 32 opens only when the inside of the cylinder portion 3 is depressurized.

  The suction passage 33 is a pipe connected to the discharge port 28. And the multi-end has reached to the lower part of the cylinder part 3. The present invention does not exclude that the multiple ends of the suction passage 33 do not reach the lower side of the cylinder portion 3.

  The metering pump 1 is provided with a leak valve (not shown). And it is possible to make the pressure in the cylinder part 3 and an external pressure into an equilibrium state via this leak valve. It is also possible to discharge the organic solvent taken into the metering pump 1 via the leak valve.

Hereinafter, operation | movement and an effect | action of the metering pump 1 which concern on this invention are demonstrated using FIGS. 2-5 according to the flow of time.
FIG. 2 is a schematic cross-sectional view of a state in which the cylinder portion 3 of the metering pump 1 according to the present invention is immersed in the tank 5 containing the organic solvent 50, and shows a stage before the organic solvent 50 is sucked. . FIG. 3 is a diagram illustrating a stage during the suction of the organic solvent 50. FIG. 4 is a diagram illustrating a stage before the organic solvent 50 is discharged. FIG. 5 is a diagram showing the discharge of the organic solvent.

  First, the cylinder part 3 of the metering pump 1 according to the present invention is immersed in the tank 5 containing the organic solvent 50. Next, injection is started from the air inlet 26a of the pressurized air Air using a machine such as a compressor. The pressurized air Air enters from the air inlet 26a and continues to be discharged from the air outlet 26c through the air passage 26b (see FIG. 2). Since the air passage port 26b has a smaller cross-sectional area than the air injection port 26a, a pressure drop occurs at the air passage port 26b due to Bernoulli's theorem. As a result, the decompression chamber 25 is decompressed. In the drawing, the pressurized air Air is indicated by a mesh pattern, and the organic solvent 50 is indicated by a set of dots.

  As the decompression chamber 25 is decompressed, a pressure drop also occurs in the cylinder portion 3. In conjunction with this, the check valve 31 opens. Then, the organic solvent 5 is sucked into the cylinder portion 3, and the organic solvent is also sucked into the decompression chamber 25. As the inside of the decompression chamber 25 is filled with the organic solvent 50, the float unit 21 starts to float on the organic solvent 50 and is pressed against the packing member 22. As a result, the opening 25a is completely closed (see FIG. 3). When the pressure in the cylinder portion 3 and the pressure in the tank 5 become constant, the check valve 32 is closed.

  On the other hand, the pressurized air Air entered from the air inlet 26a passes through the initial air introduction pipe 27a and reaches the diaphragm 23. However, since the diaphragm portion 23 is pushed upward by the elastic body 24, the diaphragm portion 23 is not lowered downward in the figure only by being pushed by the pressurized air Air. That is, the force by the elastic body 24 is superior to the force by the pressurized air Air.

  However, since the opening 25a is closed by the float portion 21 as described above, the decompression portion 25c including the suction path 25b is further decompressed from the opening 25a. This decompression is easily and accurately performed because the decompression unit 25c is a small space. As a result, the suction force of the decompression unit 25c that has been further decompressed is added to the downward force of the pressurized air Air that has passed through the initial air introduction tube 27a, and surpasses the upward force of the elastic force 24. That is, the downward force is stronger than the upward force.

  Since the force for holding the diaphragm portion 23 is superior to the downward force, although not shown, the diaphragm portion 23 is lowered. That is, the vicinity of the center of the diaphragm portion 23 bends downward. As a result, the initial air introduction pipe 27a and the air introduction pipe 27b are connected, and the pressurized air Air flows and is supplied to the air introduction pipe 27b (see FIG. 4).

  Pressurized air Air that has flowed into the air introduction pipe 27b reaches the inside of the cylinder portion 3 via 27c and 27d and the pressure reduction pipe 25d. As a result, the organic solvent 50 is pressurized by the pressurized air Air. In this state, when the container 100 is connected to the discharge port 28 via the hose 101 and the valve 29 is opened, the container 100 is filled with the organic solvent 50. Furthermore, if it continues, pressurized air will be filled in the container 100 until it will become substantially the same pressure as the pressure of the supplied pressurized air Air (refer FIG. 5). When filling is completed, the supply of pressurized air is stopped. As a result, the float portion 21 is lowered and the decompression chamber 25 becomes the same as the external pressure. That is, it becomes an atmospheric pressure state. In addition, when discharging the organic solvent 50 in the metering pump 1, a leak valve (not shown) may be used.

  By the way, the present invention can be configured not to include the valve 29 as described above. The outline of the operation flow of the metering pump 1 in that case is shown below. The flow of this operation is almost the same as described above.

  First, the cylinder part 3 of the metering pump 1 according to the present invention is immersed in the tank 5 containing the organic solvent 50. Before and after this, the container 100 is connected to the discharge port 28 via the hose 101. Add pressurized air Air. The decompression chamber 25 becomes negative pressure. The check valve 32 at the bottom of the cylinder part 3 is opened, and the organic solvent enters the cylinder part 3. The organic solvent 50 reaches the decompression chamber 25 and the float unit 21 is pushed up. The float portion 21 is in close contact with the packing member 22. On the other hand, the upper diaphragm portion 23 is pushed upward by the elastic body 24 and overcomes the force of being pushed down by the pressurized air Air. Further, when the pressurized air Air is supplied, the negative pressure in the pressure reducing portion 25c is further increased, and the elastic body 24 supporting the diaphragm portion 23 is lowered. Pressurized air Air rapidly flows and the organic solvent 50 inside is filled in the container 100. When the organic solvent 50 is filled, the container 100 is further filled with air until the pressure is substantially the same as the pressure of the supplied pressurized air Air. When filling is completed, the air supply is stopped. The float unit 21 is lowered to the atmospheric pressure state.

  According to the above-described metering pump 1 according to the present invention, since there is no mechanical sliding portion inside, the container 100 can be easily filled even with a flammable organic solvent such as alcohol or acetone. become able to. In addition, since it is moved by pressurized air instead of a motor or electricity, the container can be filled safely without causing problems such as ignition of highly flammable organic solvents such as alcohol and acetone. . Furthermore, the volume of the fluid to be discharged is not limited to the volume of the pump chamber, and can be adjusted to the container for storing the discharged fluid.

  The embodiment of the metering pump according to the present invention has been described above. However, the present invention is not limited to the above-described embodiment. In addition, the metering pump according to the present invention can be used not only for organic solvents but also for handling various other liquids.

It is a schematic sectional drawing in one embodiment of a metering pump concerning the present invention. It is a schematic sectional drawing of the state where a cylinder part of a metering pump concerning the present invention was immersed in a tank containing an organic solvent, and is a figure showing a stage before suction of an organic solvent. It is the schematic sectional drawing of the state where the cylinder part of the metering pump concerning the present invention was immersed in the tank containing the organic solvent, and is the figure showing the stage in the suction of the organic solvent. It is a schematic sectional drawing of the state where the cylinder part of the metering pump concerning the present invention was immersed in the tank containing organic solvent, and is a figure showing the stage before discharge of organic solvent. It is a schematic sectional drawing of the state where the cylinder part of the metering pump concerning the present invention was immersed in the tank containing the organic solvent, and is a figure showing discharge of the organic solvent.

Explanation of symbols

1 Metering pump 2 Pump body
2A Pump body upper body 2B Pump body middle body
2C Pump body lower body 2D bolt
21 Float 22 Packing material
23 Diaphragm part 24 Elastic body
25 Decompression chamber 26 Air access path
27 Air passage tube 28 Discharge port 3 Cylinder
31 Suction port 32 Check valve
33 Suction passage 5 Tank 50 Organic solvent 100 Container 101 Hose

Claims (6)

In a metering pump that sucks and discharges a predetermined amount of liquid,
An air inlet, an air passage, and an air outlet, the air inlet and the air outlet having an air inlet / outlet passage having a relatively larger diameter than the air passage, the air A pump body having a decompression chamber that is decompressed via a suction path communicating with the air passage by introducing pressurized air from an inlet ;
A cylinder portion that is arranged to communicate with the decompression chamber and sucks the liquid, and has a suction passage that discharges the liquid sucked inside from a discharge port provided in the pump body. A cylinder portion provided ; and
Wherein disposed in a vacuum chamber, closes between said suction passage and said vacuum chamber and levitated by the buoyancy when a predetermined amount of the liquid by the vacuum chamber is reduced is sucked through the cylinder portion A float part ;
A decompression unit including the suction path blocked by the float unit, communicating with the air passage and having a diaphragm unit disposed on the upper side thereof, from the decompression chamber blocked by the float unit a pressure reducing unit that is also a further reduced pressure,
With
The diaphragm portion is
An initial air introduction pipe provided so as to communicate with the air inlet and an air introduction pipe that guides the pressurized air introduced through the initial air introduction pipe to the cylinder portion can be opened and closed. And
The pressurized air introduced through the initial air introduction pipe is formed so as to pressurize the diaphragm portion from the side opposite to the decompression portion side, and when the liquid is sucked into the decompression chamber, While blocking the flow of the pressurized air into the air introduction pipe against the pressure of the pressurized air introduced through the air introduction pipe, the decompression chamber is blocked by the float portion. A metering pump characterized by being configured to open and introduce the pressurized air into an air introduction pipe arranged to communicate with the cylinder part and the decompression chamber when the decompression part is further decompressed . The metering pump according to claim 1,
A metering pump, wherein the cylinder part is provided with a suction port for sucking a liquid, and a check valve is provided in the suction port. The metering pump according to claim 1 or 2,
The float portion has a substantially spherical shape, and is configured to close the suction path for air in the decompression chamber by sealing the substantially circular opening formed in the suction path with its curved surface. A metering pump characterized by that. The metering pump according to claim 3,
A metering pump characterized in that a packing member is disposed around the opening so as to be in close contact with the surface of the float part without any gap. In the metering pump according to any one of claims 1 to 4,
The diaphragm portion resists pressure that pressurizes the diaphragm portion from the side opposite to the decompression portion side by the pressurized air introduced through the initial air introduction pipe when the decompression chamber is decompressed. When the float portion closes the suction path without opening, the internal pressure of the pressure reducing portion is at least lower than the internal pressure of the pressure reducing chamber , and the additional air introduced through the initial air introduction pipe is used. A metering pump, wherein the metering pump is held by an elastic body so as to be opened by a pressure that pressurizes the diaphragm portion from a side opposite to the pressure reducing portion side by pressurized air . In the metering pump according to any one of claims 1 to 5,
The pump body is provided with a discharge port, and a hose for filling a liquid in a predetermined container can be attached to the discharge port.
The decompression chamber and the cylinder part are communicated with each other via a decompression pipe, and the decompression pipe is connected to the air introduction pipe via a valve, and the valve does not open from the decompression pipe side, but the air introduction pipe It is formed to open from the side,
Thus, the metering pump can be filled with the liquid sucked into the cylinder portion and the pressurized air into the container.

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