JP7022337B2 - Water treatment equipment - Google Patents

Description

The present invention relates to a water treatment apparatus.

Conventionally, high-purity pure water containing no impurities has been used in the manufacture of pharmaceuticals and cosmetics, the cleaning of electronic parts, precision equipment, and the like. As an apparatus for producing this kind of pure water, a water treatment apparatus such as a pure water production apparatus may be used. In this water treatment apparatus, pure water is produced by membrane separation treatment of raw water such as groundwater and tap water with a reverse osmosis membrane module (hereinafter, also referred to as “RO membrane module”). Conventionally, a water treatment apparatus provided with a plurality of RO membrane modules has been known in order to produce pure water having higher purity (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-188465

In a conventional water treatment apparatus, the RO membrane module is fixed by sandwiching both ends in the longitudinal direction with saddle bands having a substantially Ω shape from the vertical direction. In this structure, since the fastening portion of the saddle band protrudes to the side of the RO membrane module, a space for fastening work is required in the left-right direction of the RO membrane module, and the external dimensions of the unit holding the RO membrane module become large. .. Therefore, in a configuration including a plurality of RO membrane modules, it has been desired to make a more compact water treatment apparatus without impairing workability.

An object of the present invention is to provide a water treatment apparatus that is more compact and has excellent workability in a configuration including a plurality of reverse osmosis membrane modules.

The present invention is a water treatment apparatus including a plurality of reverse osmosis membrane modules, in which the vessels of the plurality of reverse osmosis membrane modules are arranged so that their longitudinal directions extend laterally, and a holding member for holding the vessels. Is a plate-shaped member, an insertion hole opened in the plate-shaped member and into which the vessel is inserted, and a lower portion of the vessel attached in the vicinity of the insertion hole in the plate-shaped member and inserted into the insertion hole. The upper support member comprises a lower support member for supporting the upper part of the vessel, and an upper support member attached to the vicinity of the insertion hole of the plate-shaped member and supporting the upper part of the vessel inserted into the insertion hole. The present invention relates to a water treatment apparatus including a connecting member connected to the plate-shaped member and an urging member attached to the connecting member and elastically urging the upper portion of the vessel.

It is preferable that the upper support member further includes a pressing member that increases the urging force of the vessel to the upper part of the vessel by pressing the urging member.

According to the present invention, it is possible to provide a water treatment apparatus that is more compact and has excellent workability in a configuration including a plurality of reverse osmosis membrane modules.

It is a perspective view when the water treatment apparatus connection unit U1 of 1st Embodiment is seen from the front side. It is a perspective view when the water treatment apparatus connection unit U1 of 1st Embodiment is seen from the rear side. It is a front view of the water treatment apparatus connection unit U1. It is a perspective view when the water treatment apparatus 2 is seen from the front side. It is a perspective view when the water treatment apparatus 2 is seen from the rear side. (A) is a front view of the holding panel 21. (B) is a rear view of the holding panel 21. It is a flow chart which shows the path of the water which circulates in a water treatment apparatus 2. It is a perspective view when the water treatment apparatus 2 is seen from the rear side. It is a perspective view when the water treatment apparatus 2 is seen from the rear side. It is a perspective view which shows the structure of the RO membrane module 10. It is a perspective view which shows how the vessel 12 is attached to the holding panel 21. It is an exploded perspective view which shows how the RO membrane element 11 and the vessel sealant 30 are attached to a vessel 12. It is a perspective view when the lower fixing tool 22 and the upper fixing tool 23 are seen from the back side. It is a layout drawing of the lower fixing tool 22 and the upper fixing tool 23 attached to the holding panel 21. (A) and (B) are conceptual diagrams showing how the vessel 12 is pressed by the upper fixture 23. It is an exploded perspective view of the vessel sealing body 30. It is a partial cross-sectional view in the YZ plane of the vessel sealing body 30 attached to the vessel 12. (A) to (C) are perspective views showing a procedure for attaching the vessel joint 35 to the lateral opening 311 of the vessel cap 31. (A) is an enlarged view of the P1 portion of FIG. 18 (A). (B) is an enlarged view of the P2 portion of FIG. 16 (A). (C) is a conceptual diagram showing an engaged state between the cap side claw portion 317 and the joint side claw portion 353. It is a figure which shows the positional relationship between the cap side claw portion 317 and the joint side claw portion 353. FIG. 18B is a view when viewed from the back side. FIG. 18 (C) is a view when viewed from the back side. It is a partial side view which shows the vessel 12 arranged in the lowermost side of the RO unit 3 and the vessel joint 35A. It is sectional drawing corresponding to line AA of FIG. It is a figure which shows the positional relationship between the cap side claw portion 317 and the joint side claw portion 353. It is a figure when the vessel joint 35A inserted in the vessel cap 31 is seen from the back side. It is a figure when the vessel joint 35A rotated counterclockwise after being inserted into the vessel cap 31 is viewed from the back side. It is a front view of the water treatment apparatus connection unit U2 in 2nd Embodiment.

Hereinafter, the first and second embodiments of the water treatment apparatus and the water treatment apparatus connecting unit according to the present invention will be described.
[First Embodiment]
FIG. 1 is a perspective view of the water treatment device connecting unit U1 of the first embodiment when viewed from the front side. FIG. 2 is a perspective view of the water treatment device connecting unit U1 of the first embodiment when viewed from the rear side. FIG. 3 is a front view of the water treatment device connecting unit U1. FIG. 4 is a perspective view of the water treatment device 2 when viewed from the front side. FIG. 5 is a perspective view of the water treatment device 2 when viewed from the rear side. FIG. 6A is a front view of the holding panel 21. FIG. 6B is a rear view of the holding panel 21.

In the attached drawings (excluding some parts), the coordinate systems of X, Y, and Z that are orthogonal to each other are described. In this coordinate system, the left-right direction when the water treatment device connecting unit U1 and the water treatment device 2 arranged as shown in FIG. 1 are viewed from the front is the X direction. In the X direction, the left side of the paper is the X1 direction and the right side is the X2 direction. Further, the vertical direction (height direction) when the water treatment device connecting unit U1 and the water treatment device 2 are viewed from the front is defined as the Y direction. In the Y direction, the upper side of the paper surface is the Y1 direction and the lower side is the Y2 direction. Further, the front-rear direction when the water treatment device connecting unit U1 and the water treatment device 2 are viewed from the front is defined as the Z direction. In the Z direction, the front side of the paper surface is the Z1 direction, and the rear side is the Z2 direction. In this specification and the like, the description of the direction is not limited to the above example. For example, when long members are arranged parallel to the Z direction, the front-back direction (Z direction) may be described as "longitudinal direction (Z direction)". Further, the "-direction" is also appropriately referred to as "-side" or "-direction".

<Structure of water treatment device connection unit U1>
As shown in FIGS. 1 and 2, the water treatment device connecting unit U1 (hereinafter, also referred to as “unit U1”) includes water treatment devices 2A and 2B. The water treatment devices 2A and 2B are pure water production devices having the same configuration (hereinafter, collectively referred to as "water treatment device 2"). The water treatment devices 2A and 2B are placed in close proximity to the bases B1 and B2. The base B1 is a member provided on the front side (Z1 side) of the unit U1. The base B2 is a member provided on the rear side (Z2 side) of the unit U1. The bases B1 and B2 are fixed to the floor surface in the building, for example. The bases B1 and B2 are connected to the lower support base 72 (cabinet 7) described later of the water treatment devices 2A and 2B by bolts and nuts (reference numerals omitted).

<Structure of water treatment device 2>
The water treatment device 2 includes an RO unit 3, a pressurizing pump 4, an inverter 5, a control box 6, a cabinet 7, and various devices and lines described later.
The RO unit 3 is a structure that holds the RO membrane modules 10A to 10F (hereinafter, also collectively referred to as “RO membrane module 10”). The RO unit 3 includes six RO membrane modules 10 and a holding rack (holding member) 20.

The RO membrane module 10 is a device that separates the water supply W1 into the permeated water (treated water) W2 from which the dissolved salts have been removed and the concentrated water W4 from which the dissolved salts have been concentrated. The RO membrane module 10 is configured by, for example, housing a spiral RO membrane element 11 (see FIG. 10) in a tubular vessel (pressure vessel) 12. The vessels 12 of each RO membrane module 10 are arranged in parallel as shown in FIGS. 4 and 5. Specifically, the vessels 12 are arranged in the longitudinal direction parallel to the front-rear direction (Z direction) and at equal intervals along the vertical direction (Y direction). Further, the vessel 12 (RO film module 10) is arranged in a zigzag manner along the vertical direction (Y direction) when the water treatment device 2 is viewed from the front-rear direction (Z direction). FIG. 3 shows the arrangement of the vessel 12 when the water treatment device 2 is viewed from the front direction, but the vessel 12 is also arranged in a zigzag manner when the water treatment device 2 is viewed from the rear direction. In this zigzag arrangement, each vessel 12 adjacent in the diagonal direction partially overlaps in the vertical direction and also partially overlaps in the left-right direction (X direction). The vessels 12 may be arranged in parallel in the longitudinal direction within a range that can be regarded as substantially parallel to the front-rear direction.

The holding rack 20 is a structure that holds the vessel 12 of each RO membrane module 10. The holding rack 20 is fixed on the lower support base 72 (described later) of the cabinet 7. As shown in FIGS. 4 and 5, the holding rack 20 includes a holding panel (plate-shaped member) 21, a lower fixing tool (lower supporting member) 22, an upper fixing tool (upper support member) 23, and a side panel 24. ..

The holding panel 21 is a plate-shaped member that holds both ends of the vessel 12 in the longitudinal direction. The holding panel 21 is arranged on the front side (Z1 side) and the rear side (Z2 side) of the water treatment device 2, respectively. As shown in FIGS. 6A and 6B, each holding panel 21 includes a plurality of insertion holes 210. The insertion hole 210 is a substantially circular opening through which the vessel 12 is inserted. Insertion holes 210 are provided at six locations in one holding panel 21. The insertion holes 210 are arranged in a zigzag manner along the vertical direction (Y direction) so as to face each other in the front-rear direction (Z direction) of the water treatment device 2 in the pair of holding panels 21.

As shown in FIG. 6 (A), recesses 211 and 212 are provided on the inner peripheral edge of the insertion hole 210 (in the figure, only the uppermost stage is designated with a reference numeral). The recess 211 is a U-shaped slit into which the lower fixture 22 (described later) is mounted. The recesses 211 are provided at two locations on the lower side (Y2 side) of the insertion hole 210. The recess 212 is an inverted U-shaped slit into which the upper fixture 23 (described later) is mounted. The recesses 212 are provided at two locations on the upper side (Y1 side) of the insertion hole 210. The attachment of the lower fixing tool 22 and the upper fixing tool 23 to the insertion hole 210 (holding panel 21) will be described later.

As shown in FIGS. 4 and 5, in the water treatment apparatus 2, a side panel 24 is provided between the holding panels 21 arranged on the front side (Z1 side) and the rear side (Z2 side), respectively. The side panel 24 is a plate-shaped member for ensuring the rigidity of the holding rack 20 in the front-rear direction (Z direction). One side panel 24 is provided on the upper side (Y1 side) of the holding rack 20 and one in each of the left and right directions (X direction). As will be described later, the water treatment device 2 of the present embodiment can be attached to or detached from the vessel 12 (RO membrane module 10) from the front-rear direction (Z direction) of the holding rack 20. Therefore, the water treatment apparatus 2 of the present embodiment can secure the rigidity of the holding rack 20 in the front-rear direction (Z direction) without impairing workability such as replacement and maintenance of the vessel 12 (RO membrane module 10). ..

In the conventional water treatment device, since the vessel is replaced and maintained from the side of the holding rack (X1-X2 side), it is difficult to provide a side panel on the side of the holding rack, and water treatment is performed. It required work space on the side of the device. On the other hand, in the water treatment apparatus 2 of the present embodiment, since the side panel 24 can be provided on the side of the holding rack 20, the vessel 12 can be held without impairing workability such as replacement and maintenance. The rigidity of the rack 20 can be ensured. Further, in the water treatment apparatus 2 of the present embodiment, since a work space is not required on the side, the installation space can be utilized more effectively.

The pressurizing pump 4 is a device that sucks in the water supply W1 flowing through the water supply line L1 (described later) and discharges it toward the RO membrane module 10 (RO unit 3). The pressurizing pump 4 is supplied with driving power whose frequency is converted from the inverter 5 (described later). The pressurizing pump 4 is driven at a rotation speed corresponding to the frequency of the driving power supplied from the inverter 5.

As shown in FIGS. 4 and 5, the pressurizing pump 4 is provided on the rear side (Z2 side) of the RO unit 3 in the lower support base 72 of the cabinet 7. That is, the pressurizing pump 4 is provided on the opposite side to the RO unit 3 when the water treatment device 2 is viewed from the front side (Z1 side). According to this configuration, when the water treatment device 2 is viewed from the front side (Z1 side), the pressurizing pump 4 is hidden by the RO unit 3, so that it is not visually noticeable. Further, since the pressurizing pump 4 does not protrude in the left-right direction (X direction) of the water treatment device 2, the water treatment devices 2A and 2B can be connected in a closer state.

The inverter 5 is an electric circuit device that supplies drive power whose frequency is converted to the pressurizing pump 4. The inverter 5 is electrically connected to the control box 6 (described later). A command signal is input to the inverter 5 from the control box 6. The inverter 5 outputs the drive power of the drive frequency corresponding to the command signal (current value signal or voltage value signal) input from the control box 6 to the pressurizing pump 4. As shown in FIGS. 4 and 5, the inverter 5 is provided on the upper side (Y1 side) of the back support plate 73 (described later) in the cabinet 7 in the water treatment device 2. Therefore, the inverter 5 can be easily maintained from the rear side (Z2 side) of the water treatment device 2.

The control box 6 is a facility for controlling the operation (operation) of the water treatment device 2. The control box 6 is provided with a control unit, an operation panel, a power supply device, and the like (all not shown) that control the opening / closing of the flow path and the switching of the flow path in each valve. The control box 6 is configured so that a part of the outer cover opens upward (Y1 side). The administrator can control the operation of the water treatment device 2 and check the operation status by operating the operation panel (not shown) or opening a part of the outer cover to perform maintenance and the like.

When the water treatment devices 2A and 2B are connected to form the unit U1, each control box 6 is electrically connected by a signal line (not shown). As a result, the respective control boxes 6 can transmit and receive signals to and from each other. In this case, the main control is executed in one of the control boxes 6 (for example, the water treatment device 2A), and the sub control is executed in the other control box 6 (for example, the water treatment device 2B).

As shown in FIGS. 4 and 5, the control box 6 is provided on the upper side (Y1 side) of the holding panel 21 arranged on the front side (Z1 side) of the water treatment device 2. That is, the control box 6 is provided on the opposite side of the inverter 5 with the RO unit 3 interposed therebetween in the front-rear direction (Z direction) of the water treatment device 2. According to this configuration, the noise generated by the inverter 5 is less likely to reach the control box 6, so that the influence of the noise on the control unit (not shown) housed in the control box 6 can be reduced.

The cabinet 7 is a structure for holding the RO unit 3, the pressurizing pump 4, the inverter 5, the control box 6, and various devices and lines described later.
As shown in FIGS. 4 and 5, the cabinet 7 includes an upper support base 71, a lower support base 72, and a back support plate 73.

The upper support base 71 is a member arranged on the upper side (Y1 side) of the cabinet 7. The upper support base 71 is connected to the upper side (Y1 side) of the inverter 5 at the end portion on the rear side (Z2 side). As described above, the inverter 5 is provided on the upper side (Y1 side) of the back support plate 73 (described later) of the cabinet 7. Further, the upper support base 71 is connected to the upper end (Y1 side) of the holding panel 21 arranged on the rear side (Z2 side) at a substantially intermediate position in the longitudinal direction (Z direction).

Although not shown in FIGS. 4 and 5 because they are covered by the control box 6, the upper support base 71 is located on the upper side (Y1 side) of the holding panel 21 at the end portion on the front side (Z1 side). Connected to the end.

As shown in FIGS. 4 and 5, bolt holes 75 are provided on both side surfaces of the upper support base 71 in the left-right direction (X direction). Bolt holes 75 are provided at two locations on both side surfaces of the upper support base 71 in the front-rear direction (Z direction). As shown in FIGS. 1 and 2, the water treatment devices 2A and 2B are placed in close proximity to the bases B1 and B2. In the water treatment devices 2A and 2B, the threaded rod 74 is inserted into the bolt hole 75 of the upper support base 71, respectively. The water treatment devices 2A and 2B are connected by fastening the nut 76 to the threaded portion of the threaded rod 74. The water treatment devices 2A and 2B are connected by using two bolt holes 75 provided on the sides facing each other.

The lower support base 72 is a member arranged on the lower side (Y2 side) of the cabinet 7. The lower support base 72 is fixed to the bases B1 and B2 by bolts and nuts (reference numerals omitted) on the front side (Z1 side) and the rear side (Z2 side) in the longitudinal direction (Z direction). The RO unit 3, the pressurizing pump 4, and the like are mounted on the upper side (Y1 side) of the lower support base 72.

The back support plate 73 is a member arranged on the rear side (Z2 side) of the cabinet 7. The back support plate 73 is provided between the upper support base 71 and the lower support base 72 on the rear side (Z2 side). The upper end (Y1 side) of the back support plate 73 is connected to the rear end (Z2 side) of the upper support base 71 via the inverter 5. The lower end (Y2 side) of the back support plate 73 is connected to the rear end (Z2 side) of the lower support base 72.

Next, the arrangement of the lines, equipment, etc. constituting the water treatment device 2 will be described.
FIG. 7 is a flow chart showing a path of water flowing through the water treatment device 2. The flow chart shown in FIG. 7 is common to the water treatment devices 2A and 2B. In the flow chart shown in FIG. 7, the valves, switches, lines and the like used for cleaning, inspection and the like are not shown.

8 and 9 are perspective views when the water treatment device 2 is viewed from the rear side. FIG. 8 is a perspective view of the water treatment device 2 when viewed from approximately halfway between the X1 direction and the Z2 direction on the rear side (Z2 side). FIG. 9 is a perspective view of the water treatment device 2 when viewed from approximately halfway between the X2 direction and the Z2 direction on the rear side (Z2 side). In FIGS. 8 and 9, in order to make it easy to understand the arrangement of various devices, lines, etc., a part of the pressurizing pump 4, the inverter 5, the control box 6, and the cabinet 7 is not shown. Further, in FIGS. 8 and 9, the mounting positions are designated with reference numerals by omitting the illustration of the sensor main body.

As shown in FIG. 7, the water treatment device 2 has, as main lines, a water supply line L1, a supply water line L2, a permeated water line L3, a concentrated water line L4, a circulating water line L5, a drainage line L6, and a permeated water discharge line. It is equipped with L7.
The term "line" as used herein is a general term for lines capable of flowing fluids such as flow paths, routes, and pipelines.

The water supply line L1 is a line that supplies water supply (raw water) W1 to the confluence portion J1 with the supply water line L2. The upstream end of the water supply line L1 is connected to the water supply line L11 extending from the supply source (not shown) of the water supply W1. A flange FL1 is provided at an upstream end (inlet end) of the water supply line L1. As shown in FIGS. 8 and 9, the flange FL1 is open above the water treatment device 2 (Y1 side) when the water treatment device 2 is viewed from the front-rear direction (Z direction), and the water treatment device 2 is open. There is no opening on the side of 2 (X1-X2 side). Further, as shown in FIGS. 8 and 9, the water supply line L1 is provided behind (Z2 side) of the plurality of RO membrane modules 10 (RO unit 3), and is provided on the side (X1-X2 side). Not provided.

As shown in FIG. 8, the inlet end portion (flange FL1) of the water supply line L1 is provided on the upper side (Y1 side) of the water treatment device 2 and opens above the water treatment device 2 as described above. Therefore, the water supply line L1 of the water treatment device 2 can be easily connected to the water supply line L11 provided at a relatively high position in the factory.

The flange FL1 is connected to the water supply connecting pipe CP1 as shown in FIGS. 1 and 2. The water supply connecting pipe CP1 is a piping member that connects the inlet ends of the water supply lines L1 of the water treatment devices 2A and 2B. As shown in FIGS. 1 and 2, the water supply connecting pipe CP1 includes flanges FL11 and FL12 arranged in the left-right direction (X direction) and flanges FL13 and FL14 arranged in the downward direction (Y2 direction). A downstream end (flange) of the water supply line L11 is connected to one of the flanges FL11 and FL12, and a shielding flange (not shown) is provided on the other side.

The flanges FL13 and FL14 are connected to the flange FL1 provided at the inlet end of each of the water supply lines L1 of the water treatment devices 2A and 2B. Inside the water supply connecting pipe CP1, the pipes connected to the flanges FL11 to FL14 communicate with each other. The configuration of the water supply connecting pipe CP1 is the same as that of the permeated water connecting pipe CP2, the first drainage connecting pipe CP3, and the second drainage connecting pipe CP4, which will be described later. Therefore, each flange provided on the permeated water connecting pipe CP2, the first drainage connecting pipe CP3, and the second drainage connecting pipe CP4 will be described with the same reference numerals (flange FL11 to FL14) as those of the water supply connecting pipe CP1.

The water supply W1 sent out from the water supply supply line L11 is supplied to the water supply lines L1 of the respective water treatment devices 2A and 2B via the water supply connecting pipe CP1. The water supply connecting pipe CP1 is provided on the rear side (Z2 side) of the unit U1. Therefore, when the unit U1 is viewed from the front side (Z1 side), the water supply connecting pipe CP1 is hidden by the RO units 3 and the like of the water treatment devices 2A and 2B, so that it is not visually noticeable.

As shown in FIGS. 7 and 8, the water supply line L1 is provided with a water supply sluice valve V1, a water supply proportional valve V2, and a merging portion J1 in this order from the upstream side to the downstream side.
The water supply sluice valve V1 is a manual valve that can operate the opening and closing of the water supply line L1. The water supply proportional valve V2 is an electric valve that continuously controls the flow rate of the water supply W1 in the range of 0 to 100%. The opening degree of the water supply proportional valve V2 is controlled by the control box 6 (control unit). Further, in the water supply line L1, a water supply pressure sensor PS1 is connected between the water supply proportional valve V2 and the merging portion J1. The water supply pressure sensor PS1 is a device that measures the pressure of the water supply W1 flowing through the water supply line L1. The pressure of the water supply W1 measured by the water supply pressure sensor PS1 is transmitted to the control box 6 (control unit).

The supply water line L2 is a line that supplies the supply water W1 to the RO membrane module 10 as the supply water W2. The upstream end of the supply water line L2 is connected to the confluence J1. The downstream end of the supply water line L2 is connected to the primary side inlet port PT1 of the RO membrane module 10A arranged on the lowermost side (Y2 side) in the RO unit 3 (see FIG. 8). The supply water line L2 is provided with a merging portion J1, a pressurizing pump 4, and an RO membrane module 10 (10A to 10F) in this order from the upstream side to the downstream side.

The merging portion J1 is a place where the water supply line L1, the supply water line L2, and the circulating water line L5 meet, and is composed of, for example, a T-shaped joint. At the merging portion J1, the supply water W1 flowing through the water supply line L1 and the circulating water W41 (described later) flowing through the circulating water line L5 merge and are sent to the pressurizing pump 4 as the supply water W2.

The pressurizing pump 4 (see FIG. 5 and the like) is a device that sucks the supply water W2 in the supply water line L2 and discharges it toward the RO membrane module 10. As described above, the pressurizing pump 4 is supplied with the driving power whose frequency is converted from the inverter 5. The pressurizing pump 4 is driven at a rotation speed corresponding to the frequency of the driving power supplied from the inverter 5. As described above, the RO membrane module 10 is a device that separates the water supply W1 into the permeated water W2 from which the dissolved salts have been removed and the concentrated water W4 from which the dissolved salts have been concentrated.

In the supply water line L2, a supply water temperature sensor TE1 is provided between the confluence portion J1 and the pressurizing pump 4 (see FIG. 8). The supply water temperature sensor TE1 is a device that measures the temperature of the supply water W2 flowing through the supply water line L2. The temperature of the supply water W2 measured by the supply water temperature sensor TE1 is transmitted to the control box 6 (control unit). Further, in the supply water line L2, the supply water pressure sensor PS2 is connected between the pressurizing pump 4 and the RO membrane module 10 (see FIG. 8). The supply water pressure sensor PS2 is a device that measures the pressure of the supply water W2 discharged from the pressurizing pump 4 in the supply water line L2. The pressure of the supply water W2 measured by the supply water pressure sensor PS2 is transmitted to the control box 6 (control unit).

The permeated water line L3 is a line that sends the permeated water W3 separated by the RO membrane module 10 to the downstream side. The upstream end of the permeate water line L3 is connected to the secondary port PT3 of the RO membrane modules 10A to 10F. Specifically, as shown in FIG. 8, the upstream side of the flexible tube FC1 is connected to the secondary side port PT3 of each RO membrane module 10. The flexible tube FC1 is a flexible metal tube. The downstream side of each flexible tube FC1 is connected to the piping manifold 15.

The piping manifold 15 is an instrument that collects the permeated water W3 sent out from the plurality of flexible tubes FC1 and sends them out to the outside. The piping manifold 15 is connected to the upstream end of the permeated water line L3. The permeated water W3 collected from the secondary side port PT3 of each RO membrane module 10 to the piping manifold 15 via the flexible tube FC1 is sent out from the piping manifold 15 toward the downstream side of the permeated water line L3. As shown in FIG. 8, the piping manifold 15 is provided on the rear side (Z2 side) of the RO unit 3 in the water treatment device 2. According to this configuration, the piping manifold 15 is hidden behind the RO unit 3 when the unit U1 is viewed from the front side (Z1 side), so that it is visually inconspicuous (see FIG. 3). Therefore, the water treatment device 2 does not spoil the appearance due to the piping manifold 15.

As shown in FIGS. 7 to 9, a flange FL2 is provided at an end portion (outlet end portion) on the downstream side of the permeated water line L3. As shown in FIGS. 8 and 9, the flange FL2 is open above the water treatment device 2 (Y1 direction) when the water treatment device 2 is viewed from the front-rear direction (Z direction), and the water treatment device 2 is open. There is no opening on the side of 2 (X1-X2 side). Further, as shown in FIGS. 8 and 9, the permeated water line L3 is provided behind (Z2 side) of the plurality of RO membrane modules 10 (RO unit 3), and is provided sideways (X1-X2 side). Is not provided.

The outlet end (flange FL2) of the permeated water line L3 is provided on the upper side (Y1 side) of the water treatment device 2 as shown in FIG. 8, and opens above the water treatment device 2 as described above. .. Therefore, the permeated water line L3 of the water treatment device 2 can be easily connected to the permeated water storage line L12 (described later) provided at a relatively high position in the factory.

As shown in FIGS. 1 and 2, the flange FL2 of the permeated water line L3 is connected to the flange FL13 or FL14 of the permeated water connecting pipe CP2. The permeated water connecting pipe CP2 is a piping member that connects the outlet ends of the permeated water lines L3 of the water treatment devices 2A and 2B, respectively. An upstream end (flange) of the permeated water storage line L12 is connected to one of the flanges FL11 and FL12 of the permeated water connecting pipe CP2, and a shielding flange (not shown) is provided on the other side.

In the unit U1, the permeated water W3 sent out to the permeated water lines L3 of the water treatment devices 2A and 2B is a permeated water storage line L12 (FIG. 7). The permeated water storage line L12 is a line that sends the permeated water W3 sent to the permeated water lines L3 of the water treatment devices 2A and 2B to the permeated water tank 100 installed outside. A check valve V6 is connected to the permeated water storage line L12. The check valve V6 is a valve for preventing the backflow of the permeated water W3 flowing through the permeated water storage line L12.

The permeated water connecting pipe CP2 is provided on the rear side (Z2 side) of the unit U1 as shown in FIGS. 1 and 2. Therefore, when the unit U1 is viewed from the front side (Z1 side), the permeated water connecting pipe CP2 is hidden by the RO units 3 and the like of the water treatment devices 2A and 2B, so that it is visually inconspicuous (see FIG. 3). ).

As shown in FIGS. 7 and 9, in the permeated water line L3, the permeated water flow rate sensor FM1, the permeated water electric conductivity sensor EC1, the permeated water sluice valve V4, and the check valve are sequentially arranged from the upstream side to the downstream side. V5 and the flow path switching valve V3 are connected.
The permeated water flow rate sensor FM1 is a device that measures the flow rate of the permeated water W3 flowing through the permeated water line L3. The flow rate of the permeated water W3 measured by the permeated water flow rate sensor FM1 is transmitted to the control box 6 (control unit). The permeated water electric conductivity sensor EC1 is a device for measuring the electric conductivity of the permeated water W3 flowing through the permeated water line L3. The electric conductivity of the permeated water W3 measured by the permeated water electric conductivity sensor EC1 is transmitted to the control box 6 (control unit). The permeation water sluice valve V4 is a manual valve that can operate the opening and closing of the permeation water line L3. The check valve V5 is a valve for preventing the backflow of the permeated water W3 flowing through the permeated water line L3.

The flow path switching valve V3 is a flow path for flowing the permeated water W3 separated by the RO membrane module 10 toward the permeated water tank 100 via the permeated water storage line L12, or a permeated water discharge line L7 (described later). It is an automatic valve that can be switched to any of the flow paths that discharge to the outside via. The flow path switching valve V3 is composed of, for example, an electric or electromagnetic three-way valve. The flow path switching valve V3 is electrically connected to the control box 6 (control unit). The switching of the flow path in the flow path switching valve V3 is controlled by the flow path switching signal transmitted from the control box 6.

The permeated water discharge line L7 is, for example, a line used in the initial blow for discharging the permeated water W3 from the start of the water treatment device 2 until the water quality of the permeated water W3 stabilizes. The upstream end of the permeated water discharge line L7 is connected to the flow path switching valve V3. On the other hand, a flange FL3 is provided at the downstream end (outlet end) of the permeated water discharge line L7. As shown in FIGS. 8 and 9, the flange FL3 opens to the rear (Z2 side) of the water treatment device 2 when the water treatment device 2 is viewed from the front-rear direction (Z direction), and is a water treatment device. There is no opening on the side of 2 (X1-X2 side).

In the above-mentioned initial blow, the permeated water W3 discharged from the permeated water discharge line L7 has a relatively high purity and may be reused. In the present embodiment, the outlet end portion (flange FL3) of the permeated water discharge line L7 is the rear side (Z2 side) of the water treatment device 2 and the outlet end portion (drainage line L6) of the drainage line L6, as shown in FIG. It is provided on the upper side (Y1 side) of the flange FL4). According to this configuration, the water treatment device 2 of the present embodiment can recover the permeated water W3 discharged at the time of initial blow from a higher position, so that the recovered permeated water W3 is returned to the upstream side of the water supply line L1 or the like. Will be easy.

As shown in FIG. 2, the flange FL3 of the permeated water discharge line L7 is connected to the flange FL13 or FL14 of the first drainage connecting pipe CP3. The first drainage connecting pipe CP3 is a piping member that connects the outlet ends of the permeated water discharge lines L7 of the water treatment devices 2A and 2B, respectively. An upstream end (flange) of the permeated water external discharge line L13 is connected to one of the flanges FL11 and FL12 of the first drainage connecting pipe CP3, and a shielding flange (not shown) is provided on the other side.

In the unit U1, the permeated water W3 sent out to the permeated water discharge lines L7 of the water treatment devices 2A and 2B is discharged to the outside of the permeated water from the outlet end of the permeated water discharge line L7 via the first drainage connecting pipe CP3. It is sent to the line L13. The permeated water external discharge line L13 is a line that sends the permeated water W3 drained from the permeated water discharge lines L7 of the water treatment devices 2A and 2B to a drainage place or a drainage facility outside the device (outside the system).

As shown in FIG. 2, the first drainage connecting pipe CP3 is provided on the rear side (Z2 side) of the unit U1. Therefore, when the unit U1 is viewed from the front side (Z1 side), the first drainage connecting pipe CP3 is hidden by the RO units 3 and the like of the water treatment devices 2A and 2B, so that it is visually inconspicuous (FIG. 3). reference).

As shown in FIG. 7, the concentrated water line L4 is a line that sends the concentrated water W4 separated by the RO membrane module 10 to the downstream side. The upstream end of the concentrated water line L4 is connected to the primary side outlet port PT2 of the RO membrane module 10F arranged on the uppermost side (Y1 side) in the RO unit 3. As shown in FIGS. 7 and 9, the downstream side of the concentrated water line L4 is connected to the upstream end of the circulating water line L5 and the drainage line L6 at the connecting portion J2, respectively.

The concentrated water line L4 is provided with a concentrated water pressure sensor PS3 and a flow rate adjusting unit V7 in this order from the upstream side to the downstream side. The concentrated water pressure sensor PS3 is a device that measures the pressure of the concentrated water W4 flowing through the concentrated water line L4. The pressure of the concentrated water W4 measured by the concentrated water pressure sensor PS3 is transmitted to the control box 6 (control unit). The flow rate adjusting unit V7 is a valve for adjusting the flow rate of the concentrated water W4 flowing to the downstream side.

The circulating water line L5 is a line that returns a part of the concentrated water W4 separated by the RO membrane module 10 to the confluence J1 as circulating water W41. The upstream end of the circulating water line L5 is connected to the concentrated water line L4 and the drainage line L6 at the connecting portion J2. Further, the downstream end of the circulating water line L5 is connected to the water supply line L1 and the supply water line L2 at the confluence portion J1. At the merging portion J1, the supply water W1 and the circulating water W41 (concentrated water W4) are mixed and sent out as supply water W2 to the suction port side of the pressurizing pump 4. A control valve V8 with a check valve (see FIG. 9) is connected to the circulating water line L5. The control valve V8 with a check valve is a manual valve that has a check valve function and can adjust the opening degree of the circulating water line L5. The control valve V8 with a check valve functions as a check valve during normal operation.

The drainage line L6 is a line for draining the rest of the concentrated water W4 separated by the RO membrane module 10 to the outside of the device (outside the system) as the drainage W42. The upstream end of the drainage line L6 is connected to the concentrated water line L4 and the circulating water line L5 at the connecting portion J2. As shown in FIGS. 7 to 9, a flange FL4 is provided at an end portion (outlet end portion) on the downstream side of the drainage line L6. As shown in FIGS. 8 and 9, the flange FL4 opens to the rear (Z2 side) of the water treatment device 2 when the water treatment device 2 is viewed from the front-rear direction (Z direction), and is a water treatment device. There is no opening on the side of 2 (X1-X2 side). Further, as shown in FIGS. 8 and 9, the drainage line L6 is provided behind (Z2 side) of the plurality of RO membrane modules 10 (RO unit 3), and is provided on the side (X1-X2 side). Not provided.

As shown in FIG. 2, the flange FL4 of the drainage line L6 is connected to the flange FL13 or FL14 of the second drainage connecting pipe CP4. The second drainage connecting pipe CP4 is a piping member that connects the outlet ends of the drainage lines L6 of the water treatment devices 2A and 2B, respectively. An upstream end (flange) of the concentrated water external discharge line L14 is connected to one of the flanges FL11 and FL12 of the first drainage connecting pipe CP3, and a shielding flange (not shown) is provided on the other side.

In the unit U1, the drainage W42 sent to the respective drainage lines L6 of the water treatment devices 2A and 2B is sent from the outlet end of the drainage line L6 to the concentrated water external discharge line L14 via the second drainage connecting pipe CP4. To. The concentrated water external discharge line L14 is a line that sends the drainage W42 drained from the drainage line L6 to a drainage place or a drainage facility outside the device (outside the system).

As shown in FIGS. 7 and 9, the drainage line L6 is provided with a drainage proportional valve V9, a drainage sluice valve V10, and a drainage flow rate sensor FM2 in this order from the upstream side to the downstream side. The drainage proportional valve V9 is an electric valve that continuously controls the flow rate of the drainage W42 in the range of 0 to 100%. The opening degree of the drainage proportional valve V9 is controlled by the control box 6 (control unit). By appropriately controlling the opening degree of the drainage proportional valve V9, the flow rate of the drainage W42 discharged to the outside of the device can be adjusted. By this adjustment, the recovery rate of the permeated water W3 can be maintained at a preset value. The recovery rate of the permeated water W3 means the ratio (%) of the permeated water W3 to the flow rate of the supplied water W2 supplied to the RO membrane module 10. The drainage sluice valve V10 is a manual valve that can operate the opening and closing of the drainage line L6. The drainage flow rate sensor FM2 is a device that measures the flow rate of the drainage W42 flowing through the drainage line L6. The flow rate of the drainage W42 measured by the drainage flow rate sensor FM2 is transmitted to the control box 6 (control unit).

<Structure of RO membrane module 10>
Next, the configuration of the RO membrane module 10 held in the RO unit 3 will be described.
FIG. 10 is a perspective view showing the configuration of the RO membrane module 10. FIG. 11 is a perspective view showing how the vessel 12 is attached to the holding panel 21. FIG. 12 is an exploded perspective view showing how the RO membrane element 11 and the vessel encapsulant 30 are attached to the vessel 12.

As shown in FIG. 10, the RO membrane module 10 includes an RO membrane element 11, a vessel 12, and a vessel encapsulant 30. In the RO membrane module 10, vessel sealing bodies 30 are provided at both ends of the RO membrane element 11 housed in the vessel 12 in the longitudinal direction (Z direction). The vessel sealing body 30 is a structure including an inlet of the supply water W2, an outlet of the permeated water W3, and an outlet of the concentrated water W4. The vessel seal 30 includes a side opening 311 and a central opening 312 (described later). In the vessel sealing body 30 provided on the Z2 side of FIG. 10, only the side opening 311 is shown.

Next, the role of the side opening 311 in each RO membrane module 10 will be described.
As shown in FIG. 5, in the RO membrane module 10A arranged on the lowermost side (Y2 side) of the RO unit 3, the side opening 311 of the vessel sealer 30 arranged on the rear side (Z2 side) is , It becomes the inlet of the supply water W2 (primary side inlet port PT1). Further, as shown in FIG. 4, in the RO membrane module 10A, the side opening 311 of the vessel encapsulant 30 arranged on the front side (Z1 side) is the outlet of the concentrated water W4 (primary side outlet port PT2). Become.

In the RO membrane modules 10B, 10D and 10F shown in FIG. 4, the side opening 311 of the vessel encapsulant 30 arranged on the front side (Z1 side) serves as an inlet for the concentrated water W4. Further, in the RO membrane modules 10B, 10D and 10F, the side opening 311 (not shown) of the vessel encapsulant 30 arranged on the rear side (Z2 side) is the outlet of the concentrated water W4 (primary side outlet port PT2). ).

In the RO membrane modules 10C and 10E shown in FIG. 4, the side opening 311 of the vessel encapsulant 30 arranged on the front side (Z1 side) serves as an outlet (primary side outlet port PT2) of the concentrated water W4. Further, in the RO membrane modules 10C and 10E, the side opening 311 of the vessel encapsulant 30 arranged on the rear side (Z2 side) serves as an inlet for the concentrated water W4.
In the RO unit 3, the concentrated water W4 passes through the upper RO membrane modules 10B to 10E step by step in order from the lowermost RO membrane module 10A (Y2 side), and the uppermost RO membrane module 10F. Is discharged to the outside of the RO unit 3.

Further, in FIG. 5, the central opening 312 (only the front side is shown) of the vessel encapsulant 30 arranged on the rear side (Z2 side) of the RO membrane modules 10A to 10F is the outlet (secondary side) of the permeated water W3. Port). The upstream side of the flexible tube FC1 is connected to the central opening 312 which is the secondary port. The piping manifold 15 described above is connected to the downstream side of the flexible tube FC1. Further, as shown in FIG. 4, the central opening 312 of the vessel encapsulation body 30 arranged on the front side (Z1 side) of the RO membrane modules 10A to 10F has a sealing cap 37 (only the RO membrane module 10F has a reference numeral). Is described) is attached.

The RO membrane module 10 described above is held in the holding rack 20 of the RO unit 3 (see FIGS. 1 to 5). When mounting the RO membrane module 10 on the holding rack 20, first, as shown in FIG. 11, the vessel 12 is inserted into the insertion hole 210 provided in the holding panel 21. The vessel 12 is inserted into the insertion hole 210 with the lower fixing tool 22 and the upper fixing tool 23 (described later) attached to the insertion hole 210. Subsequently, as shown in FIG. 12, the RO membrane element 11 is housed inside the vessel 12 inserted through the holding panel 21, and the vessel encapsulant 30 composed of a plurality of parts is further attached by a procedure described later. ..

<Structure of Lower Fixture 22 and Upper Fixture 23>
Next, the structures of the lower fixing tool 22 and the upper fixing tool 23 attached to the holding panel 21 (holding rack 20) will be described.
FIG. 13 is a perspective view of the lower fixing tool 22 and the upper fixing tool 23 when viewed from the back side. FIG. 14 is a layout drawing of the lower fixing tool 22 and the upper fixing tool 23 attached to the holding panel 21. Note that FIGS. 13 and 14 show an example in which the lower fixing tool 22 and the upper fixing tool 23 are attached to the holding panel 21 on the front side (Z1 side) as shown in FIG.

The lower fixture 22 is a structure that supports the lower portion of the vessel 12 (RO membrane module 10) inserted into the insertion hole 210 of the holding panel 21. The lower fixative 22 is attached along the inner peripheral edge of the lower side (Y2 side) of the insertion hole 210. As shown in FIGS. 13 and 14, the lower fixative 22 includes a fixture body 221, an engagement piece 222, a bolt hole 223 and a bolt 224.

In the present embodiment, the basic structure of the lower fixing tool 22 is the same as that of the upper fixing tool 23 described later. The fixative body 221, engagement piece 222, bolt hole 223 and bolt 224 of the lower fixture 22 correspond to the fixture body 231, engagement piece 232, bolt hole 233 and bolt 238 of the upper fixture 23. The lower fixture 22 is different from the upper fixture 23 in that it does not have a leaf spring 235 and a presser bolt 237. In the lower fixture 22, other configurations are the same as in the upper fixture 23. Therefore, as the explanation of the lower fixing tool 22, the explanation of the upper fixing tool 23 described later will be referred to. The lower fixing tool 22 may have a different configuration from the upper fixing tool 23.

The upper fixture 23 is a structure that supports the upper part of the vessel 12 (RO membrane module 10) inserted into the insertion hole 210 of the holding panel 21. The upper fixative 23 is attached along the inner peripheral edge of the upper side (Y1 side) of the insertion hole 210. As shown in FIG. 13, the upper fixture 23 includes a fixture body (connecting member) 231, an engaging piece 232, a bolt hole 233, a leaf spring holding portion 234, a leaf spring (urging member) 235, and a screw hole portion 236. And a presser bolt (pressing member) 237.

The fixture body 231 is a member connected to the holding panel 21. The fixture body 231 is provided with an engaging piece 232, a bolt hole 233, and a leaf spring holding portion 234 at both ends in the longitudinal direction, respectively. The engaging piece 232 is a protrusion that engages with the recess 212 (see FIG. 6A) of the insertion hole 210. The bolt hole 233 is a hole into which a bolt 237 for attaching the upper fixture 23 is inserted. The leaf spring holding portion 234 is a portion that holds both ends of the leaf spring 235 in the longitudinal direction. The screw hole portion 236 is a threaded hole provided with a female screw (not shown). A presser bolt 237 is attached to the screw hole portion 236. The presser bolt 237 is a member that presses the leaf spring 235.

The leaf spring 235 is a member that elastically urges the upper portion of the vessel 12. As shown in FIG. 13, the leaf spring 235 is configured in an inverted V shape. By attaching the leaf spring 235 to the inside of the fixture main body 231, both ends of the leaf spring 235 are held by the leaf spring holding portion 234. Although not shown, a non-slip tape is attached to a portion (the surface on the Y2 side) where the leaf spring 235 comes into contact with the vessel 12. The end portion of the presser bolt 237 attached to the screw hole portion 236 abuts on the central portion of the leaf spring 235. As will be described later, when the presser bolt 237 attached to the screw hole portion 236 is tightened, the central portion of the leaf spring 235 is pressed downward (Y2 side) by the end portion of the presser bolt 237.

As shown in FIG. 14, the engaging pieces 222 provided at both ends of the lower fixture 22 are inserted into the recesses 211 of the insertion holes 210, respectively. In a state where the engaging piece 222 of the lower fixing tool 22 is inserted into the recess 211 of the insertion hole 210, the bolt 224 is inserted into the bolt hole 223 and a nut (not shown) is fastened from the back surface side to fasten the lower fixing tool 22. Can be attached to the bottom of the insertion hole 210.

When the lower fixture 22 is attached to the insertion hole 210, the support surface 221a of the fixture body 221 projects from the inner peripheral edge 210a of the insertion hole 210, as shown in FIG. According to this configuration, the outer peripheral surfaces 12a (see FIG. 15) at both ends of the vessel 12 inserted through the insertion hole 210 in the longitudinal direction do not come into contact with the inner peripheral edge 210a of the insertion hole 210, so that the lower side of the vessel 12 does not come into contact with each other. The outer peripheral surface 12a is less likely to be scratched.

Further, as shown in FIG. 14, the engaging pieces 232 provided at both ends of the upper fixture 23 are inserted into the recesses 212 of the insertion holes 210, respectively. In a state where the engaging piece 232 of the upper fixing tool 23 is inserted into the recess 212 of the insertion hole 210, the bolt 238 is inserted into the bolt hole 233 and a nut (not shown) is fastened from the back surface side to fasten the upper fixing tool 23. Can be attached to the top of the insertion hole 210.

Even when the upper fixture 23 is attached to the insertion hole 210, as shown in FIG. 14, the support surface 231a of the fixture body 231 projects from the inner peripheral edge 210a of the insertion hole 210. According to this configuration, the outer peripheral surface 12a (see FIG. 15) at both ends of the vessel 12 inserted through the insertion hole 210 in the longitudinal direction does not come into contact with the inner peripheral edge 210a of the insertion hole 210, so that the outer circumference on the upper side of the vessel 12 does not come into contact with each other. The surface 12a is less likely to be scratched.

When inserting the vessel 12 into the insertion hole 210, the vessel 12 is inserted between the lower fixture 22 and the upper fixture 23 with the bolt 238 of the upper fixture 23 and the nut slightly loosened. .. Then, the bolt 238 and the nut are fastened with an appropriate torque in a state where the upper fixing tool 23 is pressed against the outer peripheral surface 12a on the upper side of the vessel 12. As a result, the vessel 12 can be supported without a gap between the lower fixing tool 22 and the upper fixing tool 23.

Next, the pressing of the vessel 12 by the upper fixture 23 will be described.
15 (A) and 15 (B) are conceptual diagrams showing how the vessel 12 is pressed by the upper fixture 23. 15 (A) and 15 (B) correspond to a perspective view of the upper fixture 23 when viewed from the back surface side. In FIGS. 15A and 15B, the holding panel 21 (holding rack 20) and the like are not shown.

As shown in FIG. 15A, in the vessel 12 inserted between the lower fixing tool 22 (not shown) and the upper fixing tool 23, the upper outer peripheral surface (supported surface) 12a is the upper fixing tool 23. It is supported by the support surface 231a of. Further, the outer peripheral surface of the lower portion of the vessel 12 is supported by the support surface 221a (see FIG. 14) of the lower fixture 22. In this state, the leaf spring 235 abuts on the outer peripheral surface 12a on the upper portion of the vessel 12 and elastically urges the outer peripheral surface 12a. From this state, when the presser bolt 237 fitted in the screw hole portion 236 is screwed in, as shown in FIG. 15B, the leaf spring 235 is further pressed toward the vessel 12 by the presser bolt 237, so that the vessel 12 The urging force on the outer peripheral surface 12a of the upper part of the is increased. Therefore, the vessel 12 can be supported more firmly between the lower fixing tool 22 and the upper fixing tool 23. When replacing or maintaining the RO membrane module 10, the presser bolt 237 is loosened to release the pressing of the vessel 12 by the leaf spring 235, whereby the vessel 12 is pulled out from the insertion hole 210 of the holding panel 21. be able to.

<Structure of vessel sealing body 30>
Next, the configuration of the vessel sealing body 30 and its attachment to the vessel 12 will be described.
FIG. 16 is an exploded perspective view of the vessel encapsulating body 30. FIG. 17 is a cross-sectional view of the vessel encapsulant 30 attached to the vessel 12 in the YY plane.
As shown in FIG. 16, the vessel sealing body 30 includes a vessel cap (lid member) 31, a water collecting pipe 32, a lock key 33, a lock key support 34, a vessel joint (joint member) 35, and a lock ring 36.

In the RO membrane module 10, the configurations of the vessel encapsulants 30 provided at both ends in the longitudinal direction (Z direction) are the same. Therefore, here, the vessel sealing body 30 provided on the front side (Z1 side) of the RO membrane module 10 will be described. In each member constituting the vessel sealing body 30, the description of the O-ring, the groove for mounting the O-ring, and the like will be omitted.

The vessel cap 31 is a member that seals both ends of the RO film element 11 in the longitudinal direction (Z direction). The vessel cap 31 is inserted into the opening holes 121 formed at both ends of the vessel 12 in the longitudinal direction. The vessel cap 31 is configured in a substantially disk shape. The vessel cap 31 includes a side opening 311, a central opening 312, and a support receiving portion 313 on a surface 315 opposite to the RO membrane element 11. Of these, the lateral opening 311 and the central opening 312 communicate with the surface of the vessel cap 31 on the side facing the RO membrane element 11.

The side opening 311 is a portion to which the vessel joint 35 or 35A (described later) can be detachably attached from the outside. The side opening 311 is provided at a position distant from the center of the vessel cap 31 to the outside. The central opening 312 is a portion to which the flexible tube FC1 (see FIG. 8) or the sealing cap 37 is attached. The central opening 312 is provided in the center of the vessel cap 31.

The support receiving portion 313 is a portion that engages with the recess 331 of the lock key 33 and the lock key support 34 (described later). Support receiving portions 313 are provided at four locations on the outer peripheral side of the vessel cap 31 at equal intervals. The support receiving portion 313 has a female screw 314 that fits with the screw 342 (described later) of the lock key support 34.

The water collecting pipe 32 is a pipe that discharges the permeated water W3 collected in the radial center of the RO membrane element 11 toward the central opening 312. As shown in FIG. 17, one end of the water collecting pipe 32 is inserted into the central opening hole 111 of the RO membrane element 11. Further, the other end of the water collecting pipe 32 is connected to the central opening 312 of the vessel cap 31. The permeated water W3 collected in the central portion of the RO membrane element 11 is sent out from the central opening 312 to the flexible tube FC1 (see FIG. 8) via the catchment pipe 32. On the other hand, in the RO membrane module 10, the sealing cap 37 is attached to the vessel cap 31 on the side (Z1 side) to which the flexible tube FC1 is not connected. Therefore, in the RO membrane module 10, the permeated water W3 is sent only to the side (Z2 side) to which the flexible tube FC1 is connected.

The lock key 33 is a member that restricts the movement of the vessel cap 31 inserted inside the vessel 12 to the outside (Z1 or Z2 side). As shown in FIG. 17, the lock key 33 is fitted into the groove portion 122 provided on the opening hole 121 side of the vessel 12. The groove portion 122 is an annular recess provided on the inner peripheral surface of the vessel 12 on the opening hole 121 side. Further, as shown in FIG. 16, the lock key 33 is provided with a recess 331 substantially in the center in the circumferential direction. The recess 331 is a portion that engages with the support receiving portion 313 and the lock key support 34 of the vessel cap 31.

The lock key support 34 is a member that connects the vessel cap 31 and the lock key 33. The lock key support 34 includes a protruding piece 341 that can engage with the recess 331 of the lock key 33 on the side facing the lock key 33 (Z2 side). Further, the lock key support 34 is equipped with a screw (male screw) 342 that can be fitted with the female screw 314 of the support receiving portion 313 (vessel cap 31).

The vessel joint 35 is a member that serves as a flow path for the permeated water W3 or the concentrated water W4, and is formed in a substantially L shape. The vessel joint 35 or the vessel joint 35A is connected to the side opening 311 of the vessel cap 31, but here, the vessel joint 35 will be described as an example. The vessel joint 35A will be described later.

The vessel joint 35 includes a first connection portion 351 and a second connection portion 352. The first connection portion 351 is a portion that is detachably attached to the side opening 311 of the vessel cap 31 from the outside. The second connection portion 352 is, for example, a portion connected to the second connection portion 352 (vessel joint 35) of another adjacent RO membrane module 10 as shown in FIG. The second connecting portions 352 are connected to each other by the fixing bracket 38.

The lock ring 36 is a component that restricts the movement of the vessel joint 35 inserted into the lateral opening 311 of the vessel cap 31 in the insertion direction (ZA2 direction described later). As shown in FIG. 17, the lock ring 36 is fitted into the annular groove 355 of the vessel joint 35. The attachment / detachment mechanism between the vessel joint 35 and the vessel cap 31 will be described later.

When the vessel sealer 30 is attached to the vessel 12, the water collecting pipe 32 is inserted into the central opening hole 111 of the RO membrane element 11 as shown in FIG. Next, the vessel cap 31 is inserted into the opening hole 121 in the longitudinal direction (Z direction) of the vessel 12. Subsequently, the four lock keys 33 are engaged with the groove portion 122 provided on the opening hole 121 side of the vessel 12. At this time, the recess 331 of the lock key 33 is engaged with the support receiving portion 313 of the vessel cap 31.

Next, the protruding pieces 341 of the four lock key supports 34 are inserted between the support receiving portion 313 of the corresponding vessel cap 31 and the recess 331 of the lock key 33, respectively. Then, the screw 342 mounted on each lock key support 34 is fitted into the female screw 314 of the support receiving portion 313 and fastened. By the above work, as shown in FIG. 17, the vessel encapsulant 30 can be attached to the vessel 12. The vessel joint 35 may be attached to the vessel cap 31 before the vessel encapsulant 30 is attached to the vessel 12, or may be attached to the vessel cap 31 after the vessel encapsulant 30 is attached to the vessel 12.

Next, the attachment / detachment mechanism, attachment / detachment, and attachment / detachment of the vessel joint 35 and the vessel cap 31 will be described.
18 (A) to 18 (C) are perspective views showing a procedure for attaching the vessel joint 35 to the lateral opening 311 of the vessel cap 31. 19 (A) is an enlarged view of the P1 portion of FIG. 18 (A). 19 (B) is an enlarged view of the P2 portion of FIG. 16 (A). FIG. 19C is a conceptual diagram showing an engaged state between the cap side claw portion 317 and the joint side claw portion 353. FIG. 20 is a diagram showing the positional relationship between the cap side claw portion 317 and the joint side claw portion 353. FIG. 21 is a view when FIG. 18 (B) is viewed from the back side. FIG. 22 is a view when FIG. 18C is viewed from the back side. 20 to 22 are views when the vessel cap 31 is viewed from the ZA2 side toward the ZA1 side.

In each of the above figures, as shown in FIG. 18A, a line orthogonal to the center line C1 of the side opening 311 and the center line C2 of the center opening 312 is defined as A1. Further, the direction parallel to the line A1 is defined as the YA direction, and the direction orthogonal to the YA direction in a plan view is defined as the XA direction. Further, the direction orthogonal to the XA-YA plane (hereinafter, also referred to as “attachment / detachment direction”) is defined as the ZA direction. In the ZA direction, the direction in which the vessel joint 35 separates from the vessel cap 31 is the ZA1 direction, and the direction in which the vessel joint 35 approaches the vessel cap 31 is the ZA2 direction.

First, the attachment / detachment mechanism between the vessel cap 31 and the vessel joint 35 will be described.
As shown in FIG. 19A, the lateral opening 311 of the vessel cap 31 is provided with a cap-side claw portion 317 on the inner peripheral edge 316. The cap-side claw portion 317 is a protrusion that engages with the joint-side claw portion 353 (described later) of the vessel joint 35, and projects inward from the inner peripheral edge 316. The cap-side claw portion 317 is provided with engaging claws 317a at both ends in the circumferential direction. The engaging claw 317a is a portion that restricts the rotation of the joint side claw portion 353 (vessel joint 35) described later in the circumferential direction in a state where the vessel joint 35 is engaged with the vessel cap 31.

As shown in FIG. 20, the cap-side claw portions 317 are provided at four locations at equal intervals along the inner peripheral edge 316 of the side opening portion 311. Each cap-side claw portion 317 is provided at a position that does not intersect the line A1 or the line A2 orthogonal to the line A1. The center position in the circumferential direction between the adjacent cap-side claw portions 317 coincides with the line A1 or A2.

Further, as shown in FIG. 20, in the four cap-side claw portions 317, the distance s1 between the adjacent cap-side claw portions 317 is the length in the circumferential direction of the joint-side claw portion 353 (vessel joint 35) described later. It is set slightly longer than s2. This is because when the vessel joint 35 is inserted into the side opening 311 of the vessel cap 31, the joint-side claw portion 353 can be inserted between the adjacent cap-side claw portions 317.

On the other hand, as shown in FIG. 19B, the first connection portion 351 of the vessel joint 35 includes a joint side claw portion 353 on the outer peripheral edge 354. The joint-side claw portion 353 is a protrusion that engages with the cap-side claw portion 317 of the side opening 311 and projects outward from the outer peripheral edge 354. As shown in FIG. 20, the joint side claw portions 353 are provided at four locations at equal intervals along the outer peripheral edge 354. Each joint side claw portion 353 is provided at a position intersecting the line A1 or the line A3 orthogonal to the line A1. The center position of each joint side claw portion 353 in the circumferential direction coincides with the line A1 or A3. Further, the vessel joint 35 is configured such that the line A1 and the center line C4 of the second connecting portion 352 intersect at an angle θ1 of 45 ° in the arrangement of the first connecting portion 351 shown in FIG.

The vessel joint 35 inserted into the side opening 311 of the vessel cap 31 is rotated in a predetermined direction (for example, in the clockwise direction) to form the joint side claw portion 353 of the vessel joint 35 and the cap side claw portion 317 of the vessel cap 31. By engaging in the ZA direction, the movement of the vessel joint 35 in the circumferential direction can be restricted. Further, the vessel joint 35 is rotated in a predetermined direction (for example, counterclockwise direction) to release the engagement between the joint side claw portion 353 of the vessel joint 35 and the cap side claw portion 317 of the vessel cap 31 in the ZA direction. This makes it possible to move the joint side claw portion 353 in the ZA1 direction. As a result, the vessel joint 35 can be removed from the vessel cap 31 (side opening 311).

Next, attachment and detachment of the vessel joint 35 and the vessel cap 31 will be described.
When attaching the vessel joint 35 to the vessel cap 31, first, as shown in FIG. 18A, the center line C1 of the side opening 311 of the vessel cap 31 and the center line C3 of the first connection portion 351 of the vessel joint 35. To match. At this time, the mounting angle of the vessel joint 35 is adjusted so that the cap-side claw portion 317 of the vessel cap 31 and the joint-side claw portion 353 of the vessel joint 35 do not overlap each other on the XA-YA plane (see FIG. 20).

Next, as shown in FIG. 18A, the first connection portion 351 of the vessel joint 35 is inserted into the lateral opening 311 of the vessel cap 31 (in the direction of the arrow in the drawing). At this time, the joint-side claw portion 353 of the vessel joint 35 is moved to the ZA2 side of the cap-side claw portion 317 of the vessel cap 31. This is to prevent the joint-side claw portion 353 of the vessel joint 35 and the cap-side claw portion 317 (engagement claw 317a) of the vessel cap 31 from coming into contact with each other when the vessel joint 35 is rotated counterclockwise.

Next, as shown in FIG. 18B, the vessel joint 35 is rotated by 45 ° in the counterclockwise direction (arrow direction in the figure) with respect to the center line C1 of the side opening 311. As a result, as shown in FIG. 22, the center line C4 and the line A1 of the second connecting portion 352 of the vessel joint 35 coincide with each other on the XA-YA plane. Next, in this state, the vessel joint 35 is pulled up in the ZA1 direction (in the direction of the arrow in the figure). As a result, as shown in FIG. 19, the joint-side claw portion 353 of the vessel joint 35 and the cap-side claw portion 317 of the vessel cap 31 engage with each other. By engaging the joint side claw portion 353 of the vessel joint 35 and the cap side claw portion 317 of the vessel cap 31, the movement of the vessel joint 35 in the ZA1 direction and the circumferential direction is restricted.

Further, by pulling up the vessel joint 35 in the ZA1 direction, as shown in FIG. 18C, the annular groove 355 of the vessel joint 35 protrudes from the lateral opening 311 of the vessel cap 31. Therefore, as shown in FIG. 19, the lock ring 36 can be fitted into the annular groove 355 of the vessel joint 35. When the lock ring 36 is fitted into the annular groove 355 of the vessel joint 35, the movement of the vessel joint 35 in the ZA2 direction is restricted. As a result, the vessel joint 35 is restricted from moving in the ZA1 direction, the circumferential direction, and the ZA2 direction while being engaged with the vessel cap 31.

The positions where the cap side claw portion 317 of the vessel cap 31 and the joint side claw portion 353 of the vessel joint 35 do not overlap each other on the XA-YA plane are 90 ° and 180 ° from the position shown in FIG. 21. It also exists at positions rotated in the clockwise direction of ° and 270 °. For example, as shown in FIG. 21, when the vessel joint 35 is inserted at a position rotated 90 ° clockwise from the position shown by the solid line (the position shown by the imaginary line in the figure), the vessel joint 35 is laterally inserted. It may be rotated by 45 ° in the counterclockwise direction with respect to the center line C1 of the opening 311. Here, the counterclockwise direction refers to a direction opposite to the arrow direction shown in FIG. 18B. Also in this case, as shown in FIG. 18C, the center line C4 and the line A1 of the second connection portion 352 of the vessel joint 35 can be aligned on the XA-YA plane.

Further, although not shown, when the vessel joint 35 is inserted at a position rotated 180 ° and 270 ° clockwise from the position shown in FIG. 21, the vessel joint 35 is inserted into the center line C4 (second). The connection portion 352) can be attached to the vessel cap 31 at a position corresponding to the line A1 on the XA-YA plane or at a position rotated by 90 ° from the line A1.

In order to remove the vessel joint 35 from the vessel cap 31, the procedure opposite to that at the time of mounting described above may be performed. Since the vessel joint 35 of the present embodiment is removable from the vessel cap 31, it is possible to more efficiently perform operations such as replacement and maintenance of the RO membrane module 10.

Next, the positional relationship between the vessel 12 (RO membrane module 10A) arranged at the lowermost side of the RO unit 3 and the vessel joint 35A will be described.
FIG. 23 is a partial side view showing the vessel 12 (RO membrane module 10A) arranged at the lowermost side of the RO unit 3 and the vessel joint 35A. FIG. 24 is a cross-sectional view corresponding to line AA of FIG. 23. In addition, in FIGS. 23 and 24, only the part necessary for the explanation of the vessel joint 35A is shown.

As shown in FIG. 23, in the holding rack 20 (RO unit 3), the vessel 12 (RO membrane module 10A) arranged at the lowermost side is connected to the discharge port 41 of the pressurizing pump 4 via the vessel joint 35A. Be connected. The vessel joint 35A is a joint having basically the same connection structure as the vessel joint 35 described above. The vessel joint 35A differs from the vessel joint 35 (substantially L-shaped) in that the entire vessel is configured in a substantially crank shape.

Hereinafter, in the vessel joint 35A, the side connected to the vessel 12 will be referred to as a first connection portion 351 and the side connected to the pressurizing pump 4 will be referred to as a second connection portion 352 (see FIG. 23). Further, as shown in FIG. 24, in the vessel joint 35A, a line orthogonal to the center line C3 of the first connecting portion 351 and the center line C4 of the second connecting portion 352 is defined as A4. Further, the horizontal line passing through the center line C1 of the lateral opening 311 of the vessel cap 31 is referred to as A5.

As shown in FIG. 24, the vessel joint 35A connected to the vessel 12 (vessel sealant 30) of the RO membrane module 10A is attached at a shallow angle with respect to the horizontal direction (X direction). Since the vessel joint 35A of the present embodiment is attached at a shallow angle θ3 of about 24 ° with respect to the horizontal direction (horizontal line A4), it extends from the lower support base 72 (cabinet 7) to the center line C3 of the first connection portion 351. The height h1 can be lowered.

On the other hand, the conventional vessel joint is integrally attached so that the center line is orthogonal (90 °) to the horizontal direction (X direction). Therefore, it is necessary to raise the position of the RO membrane module 10A so that the vessel joint and the lower support base 72 do not interfere with each other. However, if the position of the RO membrane module 10A is raised, the entire water treatment device is raised, so that the stability of the device is deteriorated and the installation location is also restricted.

On the other hand, since the vessel joint 35A of the present embodiment is attached at a shallow angle with respect to the horizontal direction (horizontal line A5), it extends from the lower support base 72 (cabinet 7) to the center line C3 of the first connection portion 351. The height h1 can be lowered. According to this configuration, the overall height of the water treatment apparatus 2 can be suppressed to be lower than before, so that the stability of the apparatus can be increased and the restrictions on the installation location can be reduced. Further, since the positions of the RO membrane modules 10A to 10F can be lowered as a whole, the workability of attaching and detaching the RO membrane module 10 can be improved. Further, since the vessel joint 35A is configured to be detachably attached to the vessel cap 31 from the outside, work such as replacement and maintenance of the RO membrane module 10 can be efficiently performed.

Next, the attachment / detachment mechanism, attachment / detachment, and attachment / detachment of the vessel joint 35A and the vessel cap 31 will be described. The vessel joint 35A is different from the vessel joint 35 in the arrangement of the joint side claw portion 353. In the vessel joint 35A, other configurations are substantially the same as those of the vessel joint 35 described above. Therefore, in the description of the vessel joint 35A, the same reference numerals are given to the members and the like equivalent to the vessel joint 35 shown in FIGS. 18 and 19, and duplicate description is omitted.

FIG. 25 is a diagram showing the positional relationship between the cap side claw portion 317 and the joint side claw portion 353. FIG. 26 is a view of the vessel joint 35A inserted in the vessel cap 31 when viewed from the back side. FIG. 27 is a view of the vessel joint 35A rotated counterclockwise after being inserted into the vessel cap 31 when viewed from the back side. 25 to 27 are views when the vessel cap 31 is viewed from the ZA2 side to the ZA1 side, and corresponds to FIGS. 20 to 22 described above.

In this example, the configuration of the cap side claw portion 317 in the side opening portion 311 of the vessel cap 31 is the same as that in FIG. 20, and therefore the description thereof will be omitted.
As shown in FIG. 25, the joint side claw portions 353 of the vessel joint 35A are provided at four locations at equal intervals along the outer peripheral edge 354. Each joint side claw portion 353 is provided at a position intersecting the line A1 or the line A3 orthogonal to the line A1. The center position of each joint side claw portion 353 in the circumferential direction coincides with the line A1 or A3 as in FIG. Further, the vessel joint 35A is configured such that the line A1 and the line A4 (center line C3-C4) intersect at an angle θ2 of about 69 ° in the arrangement of the first connection portion 351 shown in FIG. 25. Since other configurations are the same as those of the vessel joint 35 shown in FIGS. 19A to 19C, the description thereof will be omitted.

Next, attachment and detachment of the vessel joint 35A and the vessel cap 31 will be described.
When the vessel joint 35A is attached to the vessel cap 31, as shown in FIG. 25, the cap side claw portion 317 of the vessel cap 31 and the joint side claw portion 353 of the vessel joint 35A do not overlap each other on the XA-YA plane. Adjust the mounting angle of the vessel joint 35.

Next, as shown in FIG. 26, the center line C1 of the side opening 311 of the vessel cap 31 and the center line C3 of the first connection portion 351 of the vessel joint 35A are aligned with each other, and the first connection portion of the vessel joint 35A is matched. 351 is inserted into the lateral opening 311 of the vessel cap 31. At this time, the joint-side claw portion 353 of the vessel joint 35A is moved to the ZA2 side (corresponding to the arrow direction in FIG. 18A) with respect to the cap-side claw portion 317 of the vessel cap 31.

Next, the vessel joint 35A is rotated by 45 ° in the clockwise direction (in the direction of the arrow in the figure) with respect to the center line C1 of the side opening 311. As a result, as shown in FIG. 27, the line A4 (center line C3-C4) of the vessel joint 35A and the line A3 orthogonal to the line A1 and the center line C3 of the first connecting portion 351 have a shallow angle of about 24 °. Cross at θ3. In FIG. 27, the line A3 orthogonal to the line A1 at the center line C3 of the first connecting portion 351 corresponds to the horizontal line A5 shown in FIG. 24.

Next, in this state, the vessel joint 35A is pulled up in the ZA1 direction (corresponding to the arrow direction in FIG. 18B). As a result, the joint-side claw portion 353 of the vessel joint 35A and the cap-side claw portion 317 of the vessel cap 31 can be engaged with each other. By engaging the joint side claw portion 353 of the vessel joint 35A with the cap side claw portion 317 of the vessel cap 31, the movement of the vessel joint 35A in the ZA1 direction and the circumferential direction is restricted.

After that, as shown in FIG. 24, by fitting the lock ring 36 into the annular groove (not shown) of the vessel joint 35A, the movement of the vessel joint 35A in the ZA1 direction, the circumferential direction, and the ZA2 direction is restricted. .. In order to remove the vessel joint 35A from the vessel cap 31, the procedure opposite to that at the time of mounting described above may be performed.

According to the water treatment device 2 of the first embodiment described above, for example, the following effects are obtained.
In the water treatment device 2 of the first embodiment, the upper outer peripheral surface 12a of the vessel 12 inserted into the insertion hole 210 of the holding rack 20 is elastically urged by the leaf spring 235 of the upper fixture 23. Therefore, the vessel 12 is supported in a state of being pressed in the vertical direction between the lower fixing tool 22 and the upper fixing tool 23. According to this configuration, the holding rack 20 does not require a space for fastening work on the side (left-right direction) of the vessel 12, so that the external dimensions of the holding rack 20 in the left-right direction can be made smaller.

Further, by releasing the pressing of the upper fixture 23 on the vessel 12 by the leaf spring 235, the vessel 12 can be removed by pulling it out from the insertion hole 210 of the holding rack 20. Further, the vessel 12 can be mounted on the holding rack 20 by pushing it through the insertion hole 210 of the holding rack 20.
Therefore, according to the water treatment device 2 of the first embodiment, it is possible to obtain a water treatment device that is more compact and has excellent workability in a configuration including a plurality of RO membrane modules 10.

Further, by screwing the presser bolt 237 of the upper fixing tool 23, the leaf spring 235 is further pressed toward the vessel 12, so that the urging force on the outer peripheral surface 12a of the upper portion of the vessel 12 increases. Therefore, the vessel 12 can be supported more firmly between the lower fixing tool 22 and the upper fixing tool 23.

[Second Embodiment]
FIG. 28 is a front view of the water treatment device connecting unit U2 in the second embodiment.
In the water treatment device connecting unit U2 (hereinafter, also referred to as “unit U2”) of the second embodiment, the vessel 12 (RO membrane module 10) is in the water treatment devices 2A and 2B along the height direction (Y direction). The point that they are arranged linearly is different from the first embodiment. In the unit U2 of the second embodiment, the other configurations are substantially the same as those of the first embodiment. Therefore, in the second embodiment, only the front view of the unit U2 corresponding to FIG. 3 of the first embodiment is shown, and the illustration of other configurations is omitted. Further, in the description and drawings of the second embodiment, the same members as those of the first embodiment are designated by the same reference numerals as those of the first embodiment, and duplicate description will be omitted.

As shown in FIG. 28, in the water treatment devices 2A and 2B of the second embodiment, the vessels 12 of the RO membrane modules 10A to 10F are arranged at equal intervals along the height direction (Y direction). Ru. Further, each vessel 12 of the RO membrane modules 10A to 10F is linearly arranged along the height direction (Y direction) in the water treatment devices 2A and 2B. The vessel 12 of the second embodiment is also arranged so that the longitudinal direction is parallel to the front-rear direction (Z direction) as in the first embodiment (see, for example, FIG. 4).
In the water treatment devices 2A and 2B of the second embodiment as well, the vessel joint 35 is detachably configured with respect to the vessel cap 31 as in the first embodiment, so that the RO membrane module 10 can be replaced, maintained, etc. Since the work can be performed more efficiently, the workability is excellent. In addition, the water treatment devices 2A and 2B of the second embodiment also have the same effects as those of the first embodiment described above.

The preferred embodiments (first and second embodiments) of the water treatment apparatus and the water treatment apparatus connecting unit according to the present invention have been described above. However, the water treatment device and the water treatment device connection unit according to the present invention are not limited to the configuration of the above-described embodiment, and can be appropriately changed.
In the embodiment, an example in which six RO membrane modules 10 are held in one RO unit 3 has been described, but the present invention is not limited thereto. One RO unit 3 may be configured to hold seven or more RO membrane modules 10. Further, one RO unit 3 may be configured to hold five or less RO membrane modules 10. For example, the RO unit 3 capable of holding 6 RO membrane modules 10 may hold 5 RO membrane modules 10. In that case, in the RO unit 3, the opening hole 121 provided on the uppermost side (Y1 side) may be closed by a cap or the like (not shown).

A plurality of water treatment device connecting units U1 (U2) of the embodiment may be further installed. For example, two water treatment device connecting units U1 (U2) may be installed side by side in the left-right direction (X direction). In that case, it is preferable to provide a space for maintenance between the two water treatment device connecting units U1 (U2). By providing such a space, in the two water treatment device connecting units U1 (U2), it is possible to maintain the water treatment devices 2 facing each other in the left-right direction from the side surface. Further, one water treatment device connecting unit U1 (U2) and one water treatment device 2A or 2B may be installed side by side in the left-right direction (X direction). Even in that case, it is preferable to provide a space for maintenance between the water treatment device connecting unit U1 (U2) and the water treatment device 2A or 2B.

U1, U2 Water treatment equipment connection unit 2,2A, 2B Water treatment equipment 3 RO unit 4 Pressurization pump 5 Inverter 6 Control box 7 Cabinet 10,10A-10F RO membrane module 11 RO membrane element 12 Vessel 15 Piping manifold 20 For holding Rack (holding member)
21 Holding panel (plate-shaped member)
22 Lower fixture (lower support member)
23 Upper fixture (upper support member)
30 Vessel sealant 31 Vessel cap 33 Lock key 34 Lock key support 35,35A Vessel fitting 210 Insertion hole 231 Fixture body (connecting member)
235 Leaf spring (urgency member)
237 Presser bolt (pressing member)
317 Cap side claw part 353 Joint side claw part B1, B2 Base CP1 Water supply connecting pipe CP2 Permeated water connecting pipe CP3 First drainage connecting pipe CP4 Second drainage connecting pipe L2 Supply water line L3 Permeated water line L4 Concentrated water line L5 Circulation Water line L6 Drainage line L7 Permeate water discharge line W1 Supply water W2 Supply water W3 Permeate water W4 Concentrated water W5 Drainage

Claims (2)

A water treatment device equipped with multiple reverse osmosis membrane modules.
The vessels of the plurality of reverse osmosis membrane modules are arranged so that their longitudinal directions extend laterally.
The holding member for holding the vessel is attached to the plate-shaped member, the insertion hole opened in the plate-shaped member and into which the vessel is inserted, and the insertion hole in the plate-shaped member, and is attached to the insertion hole. A lower support member for supporting the lower portion of the inserted vessel and an upper support member attached in the vicinity of the insertion hole of the plate-shaped member and supporting the upper portion of the vessel inserted into the insertion hole are provided. ,
The upper support member is a water treatment device including a connecting member connected to the plate-shaped member and an urging member attached to the connecting member and elastically urging the upper part of the vessel. The upper support member further includes a pressing member that increases the urging force of the urging member on the upper part of the vessel by pressing the urging member.
The water treatment apparatus according to claim 1.

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