1. Field of the Invention
The present invention relates to a tank structure provided with a member or part for reducing a deformation amount of a tank body.
2. Description of Related Art
As shown in
As shown in
Jpn. unexamined patent publication No. 9-286490(1997) discloses a tank structure 301 as shown in
In the tank structure 401 of
In the chemical liquid vessel 201 of
In the tank structure 301 of
In the conventional tank structure, a tank body may expand and be deformed by its internal pressure. For this reason, the welded portion between an exterior member and the tank body may peel or come off and the sealing strength may deteriorate. In particular, when the tank body is made of resin which is largely deformable, the welded portion between the exterior member and the tank body will peel or come off. The sealing strength may largely decrease.
Each of conventional fluid couplings is mounted in a cover covering a tank opening to connect each external pipe line to a tank. Hence, many fluid couplings corresponding to the external pipe lines have to be assembled to the tank. This may cause leakage of liquid or gas with a higher risk. In case that the assembling utilizes welding, further, an assembling cost may increase.
Moreover, the fluid couplings must be made of a specific resin, for example tetrafluoroethylene (PTFE, PFA) resin depending on chemical liquid to be treated. However, the tetrafluoroethylene resin is difficult to mold in complicated shape needed for attachment to the cover of the tank. The tetrafluoroethylene resin is relatively expensive and a completed tank will also be expensive.
The present invention has been made in view of the above circumstances and has an object to provide a tank structure with a reduced deformation amount of a tank body and stable sealing strength.
Another object of the present invention is providing a tank structure easy to assemble, and occupying only a minimum installation area.
Additional objects and advantages of the invention will be set forth in part in the description which follows and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
To achieve the purpose of the invention, there is provided a tank structure that has a tank body for storing liquid and a control device for supplying or discharging the liquid to or from the tank body, the tank structure comprising: an upper member having a lower flat surface; and a lower member having an upper flat surface; wherein the tank body has an upper flat surface and a lower flat surface which face the lower flat surface of the upper member and the upper flat surface of the lower member respectively, and the tank body is held in sandwiched relation between the upper and lower members so that the upper and lower flat surfaces of the tank body are in contact with the lower flat surface of the upper member and the upper flat surface of the lower member respectively.
According to the above invention, the first and second exterior members serve to restrain the deformation amount of the tank body, so that the sealing strength of the tank body can be stable.
According to another aspect, the present invention provides a tank structure comprising a tank body for storing liquid, a liquid supply coupling for allowing the liquid to flow in the tank body; a liquid discharge coupling for allowing the liquid to flow out of the tank body; a gas supply coupling for supplying gas to the tank body to allow the liquid to flow out of the tank body; a gas exhaust coupling for exhausting the gas from the tank body; wherein the tank structure further comprises a valve and coupling integrated unit including: a liquid supply valve for controlling a flow rate of the liquid, a gas supply valve for controlling a flow rate of the gas to be supplied; a gas exhaust valve for controlling a flow rate of the gas to be exhausted; a liquid supply passage for providing communication between the liquid supply coupling and the tank body through the liquid supply valve; and a gas passage for providing communication between the gas supply coupling and the tank body via the gas supply valve while providing communication between the gas exhaust coupling and the tank body via the gas exhaust valve.
With the above structure, when the fluid couplings previously provided with valve seats are simply fixed to the tank opening portion, the tank structure having the valve and coupling integral unit and the tank can be achieved. The fluid couplings can be integrated by a small number of parts or components to achieve space-saving.
The accompanying drawings, which are incorporated in and constitute a part of this specification illustrate an embodiment of the invention and, together with the description, serve to explain the objects, advantages and principles of the invention.
In the drawings,
A detailed description of preferred embodiments of the present invention will now be given referring to the accompanying drawings.
[Configuration of a Tank Structure in a First Embodiment]
Firstly, an external configuration of a tank structure 1 in the first embodiment will be described below.
The tank body 11 is explained below.
The upper exterior member 12 is explained below. As shown in
The lower exterior member 13 is explained below. As shown in
The above mentioned tank body 11, upper exterior member 12, and lower exterior member 13 are assembled in such a manner that the tank body 11 is sandwiched between the lower surface of the upper exterior member 12 and the upper surface of the lower exterior member 13; the bolts 14 are inserted through the holes 12a of the upper exterior member 12 into the bolt-receiving parts 13a of the lower exterior member 13 and screwed therein, thereby securing the upper and lower exterior members 12 and 13 with the bolts 14.
Next, components of the tank structure 1 for fluid control will be described.
As shown in
[Operations of the Tank Structure for the Fluid Control]
The tank structure 1 having the above configuration operates in the following manner for fluid control. Fluid is supplied to the tank structure 1 through the ports A and B of the manifold valve 21 shown in
The tank structure 1 in the present embodiment has the following features. As mentioned above, the internal pressure of the tank 11 is increased by the nitrogen gas supplied thereto through the port D. At this time, the tank body 11, made of resin, tends to expand and become deformed unless it has an external member. In the tank structure 1 in the present embodiment, however, the upper exterior member 12 is placed on the upper surface of the tank body 11 and the lower exterior member 13 is placed on the lower surface of the tank body 11 and the upper and lower exterior members 12 and 13 are secured by the bolts 14 as fastening members.
In addition, each of the exterior members 12 and 13 has a rectangular flat plate shape as mentioned above. The fastening members 14 are arranged at four corners of each of the exterior members 12 and 13. With this configuration, the fastening force of the fastening members 14 are uniformly applied over the entire exterior members 12 and 13. Hence, the fastening force of the fastening members 14 uniformly acts on the entire upper and lower surfaces of the tank body 11.
Since the fastening force of the fastening members 14 uniformly acts on the entire upper and lower surfaces of the tank body 11, it can absorb the expansion and deformation amount of the tank body 11. Thus, no load will be exerted on the welded portion 11c of the tank body 11, causing no possibility that the welded portion peels or comes off. This makes it possible to stably maintain the sealing strength of the body 11.
As shown in
To maintain the sealing strength between the tank body 11 and each control device, furthermore, a sealing member 23a may be placed between the tank body 11 and the upper exterior member 12 to axially seal them as shown in
The tank structure 1 can readily be assembled by simply mounting various control devices such as the manifold valve 21, the drain valve 22, and the sensor ports 23 on the upper surface of the upper exterior member 12.
When viewed from above the upper exterior member 12, the control devices such as the manifold valve 21, the drain valve 22, and the sensor ports 23 are positioned within the area of the upper exterior member 12. Accordingly, the installation area (space) of the tank structure 1 may be just the area (dimension) of the lower exterior member 13 slightly larger than the upper exterior member 12. Consequently, the tank structure 1 occupies only a minimum installation area.
The upper and lower exterior members 12 and 13 must have flat surfaces but may be formed in various shapes instead of the flat-plate shape. For example, a shape having turned side ends, viewed as angular U-shape in section, may be adopted.
Instead of placing the lower exterior member 13 under the tank body 11, further, the upper exterior member 12 may be secured directly to a base on which the tank body 11 is installed, by the bolts 14. In this case, the tank body 11 sandwiched between the upper exterior member 12 and the base can also reliably be prevented from expanding to become deformed.
The tank structure 1 in the present embodiment as mentioned above can have the following effects and advantages.
(1) In the above embodiment, the tank structure 1 having the tank body 11 storing fluid and the control devices for supplying or discharging the fluid to or from the tank body 11 further comprises the upper exterior member 12 having the lower flat surface and the lower exterior member 13 having the upper flat surface. The tank body 11 has the upper and lower flat surfaces facing the lower flat surface of the upper exterior member 1 and the upper flat surface of the lower exterior member 13 respectively. The tank body 11 is placed in sandwiched relation between the upper and lower exterior members 12 and 13. Accordingly, those exterior members 12 and 13 can reduce the deformation amount of the tank body 11 sufficiently to maintain the sealing strength of the tank body 11.
(2) In the tank structure having the above configuration, the tank body 11 may be held between the lower surface of the upper exterior member 12 and the upper surface of the base as mentioned above. Accordingly, the upper exterior member 12 and the base serve to reduce the deformation amount of the tank body 11 sufficiently to maintain the sealing strength of the tank body 11.
(3) Furthermore, the upper and lower exterior members 12 and 13 are made of materials having higher strength than the tank body 11. It is therefore possible to more reliably maintain the sealing strength of the tank body 11, the deformation amount of which is reduced by the exterior members 12 and 13 or by the upper exterior member 12 and the base.
(4) The tank structure 1 includes the bolts 14 fastening the upper exterior member 12 to the lower exterior member 13 or the base on which the tank body 11 is installed. In addition, arranged between the head of each bolt 14 and the upper exterior member 12 are the disc springs 16. By the resilient force of the disc springs 16, the dimension changes of the tank body 11 can be restrained even when the tank body 11 thermally expands or can be absorbed even if the tank body 11 contracts or shrinks by low-temperature fluid.
(5) In the present embodiment, the control devices are mounted on the upper surface of the upper exterior member 12 as mentioned above. Accordingly, no additional parts or members for mounting the control devices to the tank body 11 are required. Those control devices may be mounted in one way direction. Consequently, the tank structure 1 can readily be assembled.
(6) The control devices are arranged within the area of the upper surface of the upper exterior member 12, so that the tank structure 1 occupies only a minimum area.
Next, a second embodiment of the present invention will be described below with reference to
[Configuration of a Tank Structure in the Second Embodiment]
The above coupling block 111 is assembled to the tank 101 in such a manner that the first insert portion 111a holding an O-ring in the outer periphery is set in the opening of the sealing cover 102, and the externally-treaded portion 111b is threadedly engaged with the internally-threaded portion 102b of the sealing cover 102 to push the first insert portion 111a of the coupling block 111 into the small-diameter portion 102a of the sealing cover 102 sealingly. Simultaneously, the second insert portion 111c is pushed into the large-diameter portion 102c of the sealing cover 102. In the second insert portion 111c, an O-ring is arranged to prevent the valve-coupling integrated unit 110 from becoming erroneously detached from or rotating with respect to the sealing cover 102.
As shown in
Each valve (121-125) includes a body 145 integrally provided with air ports (142, 143) through which the compression air for operating the piston 144 is supplied/exhausted. Specifically, mounted in the body 145 of the valve 121 is a piston 144 which is slidably moved by the compression air supplied into the body 145 through the air ports (142, 143). A valve element 146 fixed to the end of the piston 144 blocks off the opening of the flow passage 147 to interrupt the communication to a port 141 serving as a coupling of the invention. The body 145 is secured to the coupling block 111 with bolts.
[Operations of the Tank Structure in the Second Embodiment]
Operations of the tank structure in which the sealing cover 102 and the valve-coupling integrated unit 110 are mounted on the tank 101 will be explained below.
When operation air is supplied to each valve (121-125) through the air port 143, the piston 144 is allowed to slide toward the fluid coupling block 111 until the valve element 146 is brought into contact with the valve seat 148 formed at the open end of the flow passage 147. Each valve is thus placed in a valve-closed state where the liquid supply passage 130, liquid discharge passage 135, and gas supply/exhaust passage 136 of the coupling block 111 are placed in non-communication with the relevant ports 141 connected to the liquid supply line 150 and others. When the operation air is supplied to each valve (121-125) through the air port 142, on the other hand, the piston 144 is allowed to slide away from the coupling block 111, bringing the valve element 146 out of contact with the valve seat 148 at the opening of the flow passage 147. Accordingly, the liquid supply passage 130, liquid discharge passage 135, and gas supply/exhaust passage 136 of the coupling block 111 are brought into communication with the air ports 141 connected to the liquid supply line 150 and others respectively.
When the chemical liquid stored in the tank 101 is to be discharged out of the tank 101, the valves 121, 122 and 124 are closed and the valves 123 and 125 are opened.
Hence, pressurized N2 gas (or air) is fed from the gas supply line 170 to the tank 101 through the gas supply passage 133 and gas supply/exhaust passage 136 of the coupling block 111. In this case, the tank 101 is made of tetrafluoroethylene (PTFE, PFA) resin which is low in strength. The tank 101 is controlled by the pressure reducing valve (not shown) to prevent the internal pressure of the tank 101 from exceeding a predetermined pressure. In the tank 101, the pressure of a gas layer is increased by the supplied N2 gas, pressurizing the chemical liquid of a liquid layer from above. Then, the chemical liquid is allowed to flow out of the tank 101 through the liquid discharge passage 135 extending from the coupling block 111 to near the bottom of the tank housing 104, the valve 125, and the liquid discharge line 190. At this time, the pressure of the supply gas is controlled while the pressure to be applied on the chemical liquid in the tank 101 is measured by the pressure gage (not shown). Consequently, the pressure of the chemical liquid to be discharged from the tank 101 through the liquid discharge passage 135 is controlled.
When the chemical liquid is to be supplied to the tank 101, on the other hand, the valves 123 and 125 are closed and the valves 121, 122, and 124 are opened. Then, the chemical liquid fed through the liquid supply lines 150 and 160 is allowed to pass through the open valves 121 and 122 into the tank 101 via the liquid supply passage 130 of the coupling block 111. In the tank 101, the liquid level of the liquid layer is increased by the supplied chemical liquid, decreasing the volume of the upper gas layer, thereby pressurizing the N2 gas in the tank 101. Accordingly, N2 gas is allowed to flow out of the tank 101 into the gas supply/exhaust passage 136 of the coupling block 111. At this time, the valve 123 is closed but the valve 124 is open. The N2 gas is therefore allowed to flow in the gas exhaust passage 134 without flowing in the gas supply passage 133. The N2 gas is then allowed to pass through the valve 124 and discharged through the gas discharge line 180. As above, the chemical liquid is filled in the tank 101 while discharging N2 gas therefrom.
According to the second embodiment, the valve-coupling integrated unit 110 is configured such that the coupling block 111 formed with the liquid supply passage 130, the liquid discharge passage 135, the gas supply/discharge passage 136, and the valve seats 148 is mounted on the open end side of the tank housing 104 and the valves (121-125) are mounted on the coupling block 111. The tank structure in the present embodiment can have a simple configuration.
The internally-threaded portion 111b is threadedly engaged with the externally-threaded portion 102b of the sealing cover 102 to sealingly push the first insert portion 11a of the coupling block 111 into the small-diameter portion 102a of the sealing cover 102 and the second insert portion 111c into the large-diameter portion 102 of the sealing cover 102. Thus, the coupling block 111 can readily be mounted on the tank 101 by such a simple operation. It is further possible to enhance the assembled state of the valve-coupling integrated unit 110 to the tank 101. This simple mounting operation can reduce a manufacturing cost as compared with a conventional structure. The valve-coupling integrated unit 110 may simply be mounted on the sealing cover 2 fixed to the tank housing 104. This makes it possible to facilitate maintenance in case of liquid or gas leakage as compared with a conventional structure needing a plurality of joints or couplings.
The valve-coupling integrated unit 110 is structured such that the valves (121-125) are integrally mounted on the coupling block 111. Accordingly, the section around the tank which would be complicated can be simplified and the space for a fluid circuit configured by the lines (150, 160, 170, 180, 190) can be reduced. The integrated structure allows the valves (121-125) to be concentrated in one place, so that replacement can be made easy and maintenance property can be improved.
As mentioned above, the tank structure can be achieved by a small number of integrated parts or components with space savings, and the mounted state of the valve-coupling integrated unit 110 to the tank 101 can be enhanced.
Further, as shown in
The liquid supply passage 130 extends so that its lower end is positioned lower than the lower end of the gas supply/exhaust passage 136 as shown in
The tank structure in the second embodiment as mentioned above can have the following effects and advantages.
(1) As mentioned above, the tank structure has the tank housing 104 storing chemical liquid, the liquid supply passage 130 through which the chemical liquid is supplied into the tank housing 104, the liquid discharge passage 135 through which the chemical liquid is discharged from the tank housing 104, and the gas supply/exhaust passage 136 through which gas is supplied to or exhausted from the tank housing 104. Such tank structure further comprises: the valve-coupling integrated unit 110 including the valves (121-125) for controlling the flow rate and the coupling block 111 internally provided with the liquid supply passage 130, the gas supply/exhaust passage 136, and the valve seat 148; and the tank 101 having the tank housing 104 and the sealing cover 102 having the opening (102a, 102b, 102c) in which the insert part (111a, 111b, 111c) of the coupling block 111 is engaged. Accordingly, the coupling block 111 previously formed with the valve seats 148 may be simply fixed to the sealing cover 102 to realize the tank structure having the valve-coupling integrated unit 110 and the tank 101. Such integrated space-saving structure can be achieved by a reduced number of parts or components.
(2) In the tank structure configured as above (1), the opening (102a, 102b, 102c) of the sealing cover 102 and the insert portion (111a, 111b, 111c) of the coupling block 111 are provided with respective threaded portions (102b, 111b). The threaded portion 102b of the opening (102a, 102b, 102c) of the sealing cover 102 is engaged with the threaded portion 111b of the insertion parts (111a, 111b, 111c) of the coupling block 111 to integrally connect the sealing cover 102 to the coupling block 111. Accordingly, in addition to the above mentioned effects and advantages, such integrated structure can be achieved by a further reduced number of parts or components, providing further space-saving structure. Furthermore, the sealing cover 102 and the coupling block 111 can be tightly fastened to each other by screw-engagement. This makes it possible to enhance the assembled relation of the tank 101 including the sealing cover 102 and the valve-coupling integrated unit 110 including the coupling block 111.
(3) The lower end of the gas supply/exhaust passage 136 is positioned higher than the lower end of the liquid supply passage 130 in the axial direction of the tank housing 104. This configuration makes it possible to prevent the chemical liquid supplied into the tank housing 104 through the liquid supply passage 130 from directly flowing in or entering the gas supply/exhaust passage 136. Consequently, the chemical liquid and its mist gas can be prevented from flowing out from the gas supply/exhaust passage 136.
(4) In addition, the diameter of the lower end of the gas supply/exhaust passage 136 in the axial direction of the tank housing 104 is larger than the diameter of the liquid supply passage 130. Accordingly, the flow rate in the gas supply/exhaust passage 136 can be restrained. Consequently, the chemical liquid and its mist gas can be prevented from flowing out from the gas supply/exhaust passage 136.
While the presently preferred embodiment of the present invention has been shown and described, it is to be understood that this disclosure is for the purpose of illustration and that various changes and modifications may be made without departing from the scope of the invention as set forth in the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2005-130056 | Apr 2005 | JP | national |
2005-228749 | Aug 2005 | JP | national |