This application claims the benefit of priority to Japanese Patent Application No. 2021-009316, filed on Jan. 25, 2021, the entire contents of which are hereby incorporated by reference.
The present invention relates to an intensifier and an atomizer using an intensifier.
Conventionally, an intensifier has been widely used as a device for pressurizing fluid or raw material. By pressurizing the fluid such as water to 100 to 250 MPa by using the intensifier, high-pressure water is used in various applications such as cleaning, cutting, breaking, etc. In addition, high value-added materials have been developed by using the intensifier to pressurize raw materials such as pharmaceutical materials, semiconductor materials, electronic materials, or chemical materials, or by forming fine particles by colliding high-pressure fluids of the pressurized raw materials, thereby changing physical properties and the like.
A development of the intensifier for the cleaning the apparatus or inside the system, or for preventing contamination of the raw materials has been required in the case where a high degree of cleanliness is required, or in the case where the apparatus is used for various pressurized raw materials.
To solve such problems, the intensifier including a primary cylinder for pressurizing the raw material, and a secondary cylinder for performing cleaning and discharging when the raw material leaks from the primary cylinder has been disclosed to prevent contamination of the processing liquid contained in the secondary cylinder (e.g., Japanese Patent Application Publication H06-207585).
The conventional intensifier includes the secondary cylinders arranged at both ends of the primary cylinder. Thus, the apparatus is upsized to cause problems in terms of space and cost.
Further, the conventional intensifier has a difficulty in cleaning inside the primary cylinder or the components constituting the intensifier, while preventing leakage of the pressurized raw material and allowing to perform high cleanliness processing.
Further, the raw material having high adhesiveness or abrasiveness could enter the inside of the intensifier from a slight gap during sliding of the plunger. If not cleaned properly in such a case, the pressurized raw material adhered to the surface of the plunger could apply extra load during sliding of the plunger to cause damage to the inner surface of the packing or the bottom adapter.
An object of the present invention is to provide an intensifier and an atomizer using the intensifier that allow to clean a portion to which a pressurized raw material adheres without disassembling the inside.
One or more aspects of the present invention provides an intensifier configured to pressurize raw material using medium supplied from a driving pump, the intensifier including:
a low-pressure cylinder to which the medium is supplied;
a high-pressure cylinder fixed to the low-pressure cylinder;
a piston configured to slide inside the low-pressure cylinder and the high-pressure cylinder by the medium supplied to the low-pressure cylinder;
a bottom adapter configured to pivotally support the piston; and
a resin portion disposed on an inner periphery of the bottom adapter.
The intensifier and the atomizer using the intensifier according to the present invention allow to clean the portion to which the pressurizing raw material adheres without disassembling the inside.
Embodiments will be described below with reference to the drawings as appropriate.
As shown in
As shown in
The low-pressure cylinder 3 and the high-pressure cylinder 4 each have a cylindrical shape. The low-pressure cylinder 3 and the high-pressure cylinder 4 are pressure-resistant cylinders for pressurizing the raw material M to 100 to 245 MPa. The hole 4c is a passage for supplying the raw material M from the liquid supply pump 102. The hole 4c is smaller than an inner diameter of the high-pressure cylinder 4.
The high-pressure cylinder 4 includes an inner high-pressure cylinder 4a and an outer high-pressure cylinder 4b. The inner high-pressure cylinder 4a has a space for pressurizing the raw material. The outer high-pressure cylinder 4b is disposed around the inner high-pressure cylinder 4a. The inner high-pressure cylinder 4a has high pressure resistance, and strong surface resistance against the raw material M or the like. The outer high-pressure cylinder 4b is made of a material to strongly fix members together. Providing separate characteristics to the inner high-pressure cylinder 4a and the outer high-pressure cylinder 4b improves the function of the high-pressure cylinder 4.
Reliably fixing the low-pressure cylinder 3 and the high-pressure cylinder 4 forms a single cylinder. A cylinder support 5 is disposed between the low-pressure cylinder 3 and the high-pressure cylinder 4 to suppress load applied to each of the low-pressure cylinder 3 and the high-pressure cylinder 4. The cylinder support 5, which has a cylindrical shape, fixes the low-pressure cylinder 3 and the high-pressure cylinder 4.
The low-pressure cylinder 3 and the high-pressure cylinder 4 are sealed, respectively. Thus, the medium O in the low-pressure cylinder 3 and the raw material M in the high-pressure cylinder 4 are not mixed.
Here, simply by partitioning the cylinder (the low-pressure cylinder 3, the high-pressure cylinder 4), the medium O or raw material M could enter due to the positional shift or sliding when the piston 2 slides. Thus, a bottom adapter 6 and a fixing portion 7 are disposed to the high-pressure cylinder 4 to improve the device stability.
As shown in
The surface of the bottom adapter 6 may wear due to the sliding of the piston 2 for a long time. A resin portion 10 is disposed on an inner periphery of the bottom adapter 6 to reduce the sliding load of the bottom adapter 6 and the piston 2. The resin portion 10 is detachably attached inside the bottom adapter 6. Thus, the resin portion 10 is replaceable when the resin portion 10 is worn due to the sliding of the piston 2. This eliminates replacing a large element such as the bottom adapter 6 to reduce the maintenance cost.
The material of the resin portion 10 preferably has high pressure resistance, heat resistance, and impact resistance. The material of the resin portion 10 is, for example, a thermoplastic resin. Further, a chemical load may be applied on the surface of the inner high-pressure cylinder 4a or the plunger 2b when processing is performed using a solvent with respect to the raw material M. In such a case, using a material of the resin portion 10 suitable for various solvents (acid resistance, alkali resistance, or the like) allows to improve the lifetime of the resin portion 10
Arranging the various sealing members in addition to the bottom adapter 6 that pivotally supports the piston 2 improves the sealing property. As shown in
As shown in
The cleaning liquid supply port 14 is a flow path formed on the high-pressure side of the bottom adapter 6. Cleaning liquid L is supplied from a cleaning liquid supply source Q to the cleaning liquid supply port 14. When the bottom adapter 6 is fixed by the fixing portion 7, the high-pressure cylinder 4, or the cylinder support 5 or the like, a cleaning inlet 12 is formed as a flow path for communicating the components. The cleaning liquid L is supplied from the cleaning inlet 12 to the cleaning liquid supply port 14
The cleaning liquid discharge port 15 is a flow path formed on the low-pressure side of the bottom adapter 6. The cleaning liquid L is discharged to the outside through the cleaning liquid discharge port 15. When the bottom adapter 6 is fixed by the fixing portion 7, the high-pressure cylinder 4, or the cylinder support 5 or the like, a cleaning outlet 13 is formed as a flow path for communicating the components. The cleaning liquid L is discharged to the outside from the cleaning outlet 13 via the cleaning flow path 16.
A plurality of the cleaning liquid supply ports 14 and a plurality of the cleaning liquid discharge ports 15 are uniformly arranged in the circumferential direction of the bottom adapter 6. This washes the raw material M entering the periphery of the bottom adapter 6 with the cleaning liquid L.
The cleaning outlet 13 is disposed at a position coaxially or slightly shifted with the cleaning inlet 12.
The cleaning flow path 16 is a flow path for discharging the cleaning liquid L from the cleaning liquid discharge port 15 to the outside. In a state where the bottom adapter 6 and the fixing portion 7 is fixed, the cleaning flow path 16 is formed on the outer periphery of the bottom portion and the inner periphery of the fixing portion 7. The flow path that is too large also adversely affects the fixing state of the bottom adapter 6 and the fixing portion 7, thus the flow path is constituted by the necessary minimum space.
The cleaning liquid L supplied to the cleaning inlet 12 passes through the cleaning liquid supply port 14 to lead to the gap between the high-pressure side of the inner periphery of the bottom adapter 6 and the plunger 2b. The cleaning liquid L then passes through the resin groove 10a, the cleaning liquid discharge port 15, and the cleaning flow path 16 to be discharged from the cleaning outlet 13. The cleaning liquid L circulated around the outer periphery of the bottom adapter 6 before discharged cleans the entire periphery of the bottom adapter 6.
The resin groove 10a is formed on the outer periphery of the resin portion 10. The gap between the inner peripheral surface of the bottom adapter 6 and the resin groove 10a becomes a part of the cleaning flow path for the cleaning liquid L supplied from the cleaning liquid supply port 14 to pass through during internal cleaning. The plurality of the resin grooves 10a are uniformly arranged in the circumferential direction. This cleans the raw material M entering the inside of the bottom adapter 6 with the cleaning liquid L. The resin groove 10a may have any shape such as a polygonal shape or an arc shape as long as the width allows the raw material M to be discharged with the cleaning liquid L. Further, any number (four, six, eight or the like) of the resin grooves 10a may be formed as long as the resin grooves 10a are disposed evenly in the circumferential direction.
Further, the atomizer 100 having the intensifier 1 according to the present embodiment simultaneously performs cleaning and cooling during pressurizing the raw material M without stopping the atomizer 100, which reduces the working time. Further, the atomizer 100 is applicable as a cooling mechanism before, during, or after pressurizing the raw material M.
Hereinafter, a processing procedure of the atomizer 100 according to the present embodiment will be described.
First, the raw material M to be processed is put into the raw material tank 101 to be adjusted into a slurry state. Next, the raw material M in the raw material tank 101 is supplied to the intensifier 1 by the liquid supply pump 102. The supplied raw material M is pressurized by the intensifier 1. Then, the pressurized raw material M supplied to the ejection chamber 104 after passing through the ultra-high pressure filter 103 is ejected. This process may be repeated multiple times, not only once.
Here, the procedure of the cleaning process in the intensifier 1 will be described in detail.
First, the cleaning liquid L is supplied from the cleaning liquid supply source Q to the cleaning liquid supply port 14 during the pressurizing process of the raw material M. When the bottom adapter 6 is fixed by the fixing portion 7 or the cylinder support 5, the cleaning liquid L is supplied from the cleaning inlet 12 to the cleaning liquid supply port 14. A plurality of the cleaning liquid supply ports 14 are uniformly arranged in the circumferential direction. Thus, the cleaning liquid L flows the gap of the outer periphery of the high-pressure side of the bottom adapter 6 and the inner periphery of the fixing portion 7 over the entire circumference to clean the outer periphery of the high-pressure side of the bottom adapter 6.
Next, the cleaning liquid L passes from a plurality of the cleaning liquid supply port 14 uniformly disposed in the circumferential direction through a portion of the inner periphery of the low-pressure side of the bottom adapter 6 and the inner periphery of the plunger 2b to clean the resin groove 10a.
Further, the cleaning liquid L is discharged from the cleaning liquid discharge port 15 When the bottom adapter 6 is fixed by the fixing portion 7 or the cylinder support 5, the cleaning liquid L is discharged from the cleaning outlet 13 communicating with the cleaning liquid discharge port 15.
Placing the position of the cleaning outlet 13 in a position coaxially or shifted with the cleaning inlet 12, and forming the cleaning flow path 16 that is a gap between the bottom adapter 6 and the fixing portion 7 allow to clean the outer periphery of the bottom adapter 6. In this case, the cleaning liquid L discharged from the cleaning liquid discharge port 15 passes through the cleaning flow path 16 to clean the section to the cleaning outlet 13.
This series of internal cleaning cleans the raw material M entering the inner periphery and the outer periphery of the bottom adapter 6.
In the specification, the contents for cleaning are described, but the present invention can also be applied to a cooling mechanism before, during, or after pressurizing the raw material M. Further, during pressurizing the raw material M, simultaneously performing cleaning and cooling without stopping the atomizer 100 reduces the working time.
As described above, the present invention is not limited to the above-described embodiment, and it is needless to say that the present invention can be appropriately modified without departing from the spirit thereof.
Number | Date | Country | Kind |
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2021-009316 | Jan 2021 | JP | national |