JP2003114989A - Water treatment plant estimation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water treatment plant estimation system for easily selecting a water treatment plant unit required for constructing a water treatment plant and further easily estimating a plant price required for its installation. SOLUTION: The water treatment plant estimation system is provided with a unit data base 1 in which various plant specifications of a plurality of kinds of units and their plant prices are stored, a unit selecting means 4 for selecting the unit required for constructing the water treatment plant suitable for water treatment specifications by retrieving the unit data base according to the water treatment specifications inputted via a condition input means 3 and a plant price estimating means 5 for estimating the plant price of the water treatment plant to be constructed by the selected unit. The system is further provided with a component replacement plan creating means 7 for planning a replacement plan to constitute the unit and an operation price estimating means 8 for estimating operation prices in accordance with replacement of components.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention temporarily lends out a water treatment facility constructed by using a plurality of types of units in which a plurality of types of components constituting the components of the water treatment facility are assembled according to a predetermined facility specification. At this time, the present invention relates to a water treatment equipment estimation system suitable for estimating the equipment price of the water treatment equipment.

[0002]

[Related Background Art] In a semiconductor manufacturing plant,
For example, a large amount of treated water (pure water) from which impurities such as salt have been removed is used for washing manufactured products. Therefore, in the above factory, a water treatment facility including an activated carbon filter, an ion exchanger and the like is exclusively provided as an incidental facility.

Incidentally, the above-mentioned water treatment equipment is individually designed according to the water treatment specifications such as the quantity and quality of treated water required in various factories, and is constructed as an original equipment according to the factory environment. To be done.

[0004]

By the way, in the above factory, a larger amount of treated water may be required due to the temporary expansion of the product production scale. Further, in a shipyard or the like, a large amount of treated water may be required only when the boiler is assembled to the ship. However, it is very costly to install a large-scale water treatment facility in advance in anticipation of a temporary large demand for such treated water.
In addition, since the processing capacity is not always fully exerted, there is a problem that the operation cost is extremely bad. Particularly in a shipyard, there is a problem that the operating efficiency itself is poor because the period for which water treatment equipment is required is limited.

Therefore, a plurality of types of components constituting the water treatment equipment, such as an activated carbon filter (CF), a millibore filter (MF), a reverse osmosis membrane module (RO), an electric deionization device (KCDI), a non- Regenerative ion exchanger (DZ), membrane filter (PF), degassing membrane (DC) and other components are assembled in advance according to the specified equipment specifications, and multiple types of standard water treatment equipment for rental are provided. It is considered that a water treatment facility having a desired water treatment specification is temporarily constructed by preparing them as units and renting out these units.

However, in constructing a water treatment facility having a desired water treatment specification, it is very difficult to grasp which type of unit is required and what the facility cost is. Moreover, some of the above-mentioned components need to be replaced according to their usage conditions,
It is also difficult to understand the replacement time and the operating costs associated with parts replacement.

The present invention has been made in consideration of such circumstances, and an object thereof is to simplify a water treatment equipment unit necessary for constructing the water treatment equipment when the water treatment equipment is temporarily rented out. Another object of the present invention is to provide a water treatment equipment quotation system which can be selected and can easily estimate the equipment price required for its installation. Further, the present invention provides a water treatment equipment estimation system capable of easily estimating the replacement time of a component that needs to be replaced out of a plurality of types of constituent parts constituting the component of the water treatment equipment and its operating cost. It is an object.

[0008]

In order to achieve the above-mentioned object, a water treatment equipment estimation system according to the present invention estimates the price of a water treatment equipment comprising one or a plurality of types of units. It is equipped with a unit database that stores each equipment specification and its equipment price of a plurality of types of units in which various types of component parts are assembled according to predetermined equipment specifications, and for example, the treated water quality and the treated water quantity input through the condition input means. The unit database is searched according to the water treatment specifications including the above, and one or a plurality of units necessary for constructing a water treatment facility corresponding to the water treatment specifications is selected (unit selection means), and For example, from the loan price of the water treatment facility constructed by the unit selected by searching the unit database by the unit selection means. The equipment price is estimated (equipment price estimating means), the configuration of the water treatment equipment constructed by the unit selected by the unit selecting means, and the equipment price estimated by the equipment price estimating means are provided by a predetermined information presenting means. It is characterized by having a function of presenting by using.

Further, the water treatment equipment estimation system according to the present invention further comprises a parts database which stores replacement conditions of the constituent parts constituting each of the units, for example, a general service life and the replacement price thereof. , Searching the parts database, and creating a replacement plan for the constituent parts that constitute the unit selected by the unit selecting means and need to be replaced according to the usage condition (part replacement plan creating means ), And a function of presenting the parts replacement plan via the information presenting means.

Further, the water treatment equipment estimation system according to the present invention searches the parts database according to the parts replacement plan, and requires replacement of the constituent parts as the water treatment equipment constructed by the selected units is operated. It is characterized by having a function of estimating the operation price of the water treatment facility (operation price estimation means) by checking the price of (1) and presenting this operation price together with the parts replacement plan.

The condition input means and the information presenting means are connected to a server having the unit database, the unit selecting means and the estimating means via a predetermined communication line. May be.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION A water treatment equipment estimation system according to an embodiment of the present invention will be described below with reference to the drawings. This water treatment equipment quotation system prepares a plurality of types of component parts that are constituent elements of the water treatment equipment as a plurality of types of water treatment equipment units assembled in advance according to predetermined equipment specifications, and lends out these units. It is provided in association with a water treatment facility providing system for temporarily constructing a water treatment facility having a desired water treatment specification.

By the way, a plurality of types of components constituting the components of the water treatment facility are, for example, activated carbon filter (CF), millibore filter (MF), reverse osmosis membrane module (RO),
It is composed of an electric deionization device (KCDI), a non-regeneration type ion exchanger (DZ), a membrane filter (PF), a degassing membrane (DC) and the like. In addition, each unit (water treatment equipment unit)
Is constructed by equipping a plurality of types of components for each truck / container of a predetermined size. After the container (water treatment equipment unit) is installed at the rented installation site, its water supply inlet and drainage outlet are respectively connected to the water treatment water system at the installation site, and it is configured to operate simply by supplying power. It

The water treatment equipment quotation system estimates which kind of unit to use and how much the equipment price will be when renting out such plural kinds of water treatment equipment units to construct a water treatment equipment. Furthermore, the operating cost of the water treatment facility constructed by using the above unit is estimated, and the configuration is schematically shown in FIG.

That is, this water treatment facility estimation system stores a unit database (DB) 1 which stores facility specifications such as treated water quality and treated water amount of a plurality of types of units and facility price (rental price) thereof. In addition to the above, it also includes a parts database 2 that stores replacement conditions (replacement time) of the constituent parts of each unit and the price of the parts. By the way, the information about each unit registered in the unit database 1 includes the types of main components that make up the unit and the number of used components, the treated water amount [m ³ / h], the raw water amount [m ³ / h]. , Drainage volume [m ³ /
h], raw water pressure [MPa], guaranteed water quality (treated water quality) [MΩ ・
cm] and other equipment specifications, and the rental price [yen /
Moon] etc. Further, the information on each component registered in the component database 2 includes a general service life [month or year] in a standard use situation, a component price required for replacement of the component, and the like.

The water treatment equipment estimation system basically has a condition input section for inputting water treatment specifications such as the quantity of treated water and the quality of treated water of a water treatment equipment required by a user (customer) as shown in FIG. (Condition input means) 3 and one or a plurality of units required to search the unit database 1 according to the water treatment specifications input from the condition input unit 3 and construct a water treatment facility that meets the water treatment specifications. The equipment construction unit (unit selection means) 4 for selecting the unit of (4) is provided. This equipment construction unit 4 satisfies the water treatment specifications given from the condition input unit 3 according to the equipment specifications of a plurality of types of units registered in the unit database 1, and, for example, its system configuration is the minimum. One or a plurality of units necessary for constructing the water treatment facility to be used are selected, and a recommended system configuration of the water treatment facility using the selected unit is constructed.

Further, this system searches the unit database 1 for the lending price of one or a plurality of units selected by the facility construction unit 4, and the water treatment constructed by these units. An installation cost estimation unit (equipment price estimation means) 5 for estimating the overall equipment price of the equipment is provided. And this installation cost estimation unit 5
The equipment price (estimated price) obtained in step 1 is presented to the user via the information presenting part 6 together with information on the water treatment equipment constructed by the unit selected by the equipment constructing part 4. .

This system also searches the parts database 2 according to one or a plurality of units selected by the facility construction unit 4, and selects the constituent parts of the units according to the water treatment period. , A parts replacement plan creation unit (parts replacement plan creation means) 7 that determines the replacement time of the parts that need to be replaced according to the usage status, and draws up a replacement plan for each of the replacement parts that accompanies the operation of the water treatment facility When,
An operation cost estimation unit (operation price estimation means) 8 for searching the parts database 2 for the price of the replacement part and calculating the operation cost of the water treatment facility is provided. The parts replacement plan created by the parts replacement plan creation unit 7 and the operation cost estimated by the operation cost estimation unit 8 are also presented to the user via the information presentation unit 6.

At this time, if the information on the water treatment period (equipment use period) is also input in addition to the above-mentioned water treatment specifications, the parts replacement plan and its operating cost in the input water treatment period can be obtained. Is possible. Therefore, by displaying the total of the operation cost and the facility price, it is possible to make a comprehensive estimate when the water treatment facility is temporarily introduced.

The estimation system including the above-mentioned processing units (functions) 4, 5, 7, and 8 basically starts via the condition input unit 3 as shown in an example of the processing procedure in FIG. The water treatment specification is input [step S1], and the unit database 1 is searched according to the input water treatment specification [step S2]. Then, in accordance with this search result, the facility construction unit 4 selects a unit required to construct a water treatment facility that meets the above-mentioned water treatment specifications, and constructs an example of a water treatment facility having a recommended system configuration [step S3. ]. Then, the price of the unit for constructing the water treatment equipment is obtained, the installation cost of the water treatment equipment is estimated [step S4], and the estimated price is presented together with the configuration example of the water treatment equipment [step S5].

At this time, the parts database 2 is searched according to the configuration example of the water treatment facility [step S6], and the parts replacement plan preparing section 7 is specified according to the search result while specifying the components which need to be replaced. Create a parts replacement plan for the constituent parts of the unit [step S
7]. Further, the operation cost estimating unit 8 operates so as to estimate the operation cost (part price) required for exchanging the component [step S8] and present the estimated price [step S9].

More specifically, the above-mentioned plural kinds of water treatment equipment units basically have activated carbon towers, safety filters, pumps, and reverse filters as shown in FIGS. 3 (a) to 3 (c), respectively. It is configured by connecting permeation membranes (RO membranes) in order. Then, an electric deionization device (KCDI) is provided at the rear stage of the reverse osmosis membrane (RO membrane), or a demister (D
Z) is provided as a unit having a different type (processing method). That is, the plurality of types of water treatment equipment units are a unit (A type) configured by using an electric deionization device (KCDI), a unit (B type) configured by using a dimener, and the electric deionization unit. Each is prepared as a unit (C type) configured by incorporating a degassing membrane unit into the device (KCDI).

Each of these types of units
As multiple types of units with different amounts of treated water
Has been realized. For example, an electric deionization device (KCD
The type A unit using I) has a treated water volume of 10.
0 [m³/ H] A1 type unit, and
The amount of water supply is 15.0 [m³/ H] A2 type unit
Two types are prepared as a gift. I also used the denominator
The B type unit has a treated water volume of 1.0 [m³/ H]
B1 type unit, the amount of treated water is 2.5 [m ³/ H]
B2 type unit consisting of, the amount of treated water is 5.0 [m³
/ H] B3 type unit, the amount of treated water is 10.
0 [m³/ H] B4 type unit and
The amount of water supply is 15.0 [m³/ H] B5 type unit
Five kinds are prepared as a gift.

In addition, as a unit for removing suspended solids in the raw water when handling industrial water, FIG.
A membrane type pretreatment unit (D type) as shown in Fig. 4 is prepared, and as a sub-unit for producing higher-purity pure water from the treated water generated in each unit described above, as a sub-unit, see Fig. 4 (b). The secondary pure water production unit (S type) as shown in () is prepared. The secondary pure water production unit includes, for example, a sub-tank, a sub-pump, an ultraviolet (UV) sterilizer, a deminer, and an ultrafiltration (UF) membrane.

When constructing the water treatment equipment, as shown in the concept of FIG. 5, the water treatment specifications specified from the basic water treatment units of the above-mentioned A type, B type and C type are specified. The units necessary for constructing a water treatment facility that conforms to are selectively selected, and D-type units and S-type units are further selected as needed. Depending on the water treatment specifications, a plurality of basic water treatment units are selected, and these units are used in parallel to secure the amount of treated water. Then, using these units, a water treatment facility that meets the above water treatment specifications is constructed.

FIG. 6 shows an example of an algorithm for selecting a unit required for constructing a water treatment facility that meets a specified water treatment specification from a plurality of types of units in this way. To briefly explain this algorithm, first, the required treated water quality is determined according to the water treatment specification input from the condition input unit 3 [step S10]. Specifically, the treated water quality is 5.0 [MΩ
・ High purity of cm] is required, or 1.0 [MΩ
・ Determine whether low purity of about [cm] is required. If a high-purity treated water quality of 5.0 [MΩ · cm] is required, the KCDI-installed type A or C type unit is selected as the selection candidate [step S11]. On the other hand, when a low-purity treated water quality of about 1.0 [MΩ · cm] is required, the denominator-installed B type unit is selected as the selection candidate [step S12].

When the A type or C type unit is selected as a selection candidate, it is next determined whether or not the user desires a degassing membrane type treatment that enables higher-purity water treatment. [Step S13] If the degassing membrane type process is desired, the electric deionization device (KC
A C type unit configured by incorporating a degassing membrane unit into DI) is selected [step S14]. On the other hand, when the degassing membrane type processing is not required,
Next, the required amount of treated water is determined [step S15],
Depending on the amount of treated water, for example, the amount of treated water is 10.0 [m ³
/ H] A1 type unit, or the amount of treated water is 15.
An A2 type unit of 0 [m ³ / h] is selected [step S16]. At this time, if the amount of treated water is insufficient with only one unit, type A1 or A
Two types of units are selected.

On the other hand, in the case where the type B unit equipped with a dimener is selected as a candidate for selection, the amount of treated water indicated in the water treatment specification is judged [step S17], and among the five types of unit B type described above. Then, a unit corresponding to the amount of treated water is selected [step S18]. In particular,
For example, when the amount of treated water is 1.0 [m ³ / h], B1 type unit is used. When the amount of treated water is 2.5 [m ³ / h], B1 type unit is used.
2 types of units, when the amount of treated water is 5.0 [m ³ / h], B3 type units, the amount of treated water is 10.0 [m
^In case of ³ / h], B4 type unit is selected, and in case of treated water amount of 15.0 [m ³ / h], B5 type unit is selected. Even in this case, if the amount of treated water is insufficient with only one unit, a plurality of B1-B5 units are selected.

After selecting one or a plurality of units to be the basis of water treatment as described above, it is next determined whether or not further purification is required [step S19]. That is, it is determined whether or not further high purification is required despite the selection of the above-mentioned A type or C type unit that enables high-purity water treatment. Then, when a high degree of purity such as that used in semiconductor manufacturing is required, an S type unit for further secondary treatment of the treated water by the A type or C type unit is additionally selected [step S20. ].

Whether the raw water to be treated is city water,
Alternatively, it is determined whether the water is industrial water [step S2
1]. If the raw water is industrial water, a D type unit for removing turbidity in the raw water is additionally selected [step S22]. If the raw water is city water,
If higher purity as described above is not required, D
It goes without saying that type and / or S type units are not added.

When the unit necessary for constructing the water treatment equipment conforming to the water treatment specification input from the condition input unit 3 is selected in this way, the unit is used to determine the entire system configuration [ Step S23]. That is,
Build a basic water treatment facility with one or more units of A type, B type, or C type,
If necessary, a D type unit is provided in the preceding stage and an S type unit is provided in the subsequent stage to determine the overall system configuration of the water treatment facility.

As described above, according to the estimation system of the present invention, according to the water treatment specification input from the condition input unit 3,
The units required to construct a water treatment facility that meets the water treatment specifications are selected and presented as the recommended water treatment system configuration. Under this system configuration, the equipment cost required to install the water treatment equipment is estimated and presented to the user. Furthermore, for the replacement parts including, for example, activated carbon and ion exchange resin in the unit that constructs the water treatment facility, a part replacement plan is planned when the water treatment facility is operated, and the operating cost associated with the part replacement is estimated. It will be.

Therefore, the user (customer) only needs to input the necessary water treatment conditions (water treatment specifications) and the units necessary for constructing the water treatment equipment necessary for the water treatment,
Since the cost (equipment price) required to install the water treatment equipment, the operating cost, and the like are presented, it becomes possible to easily plan a temporary water treatment equipment installation plan. Moreover, including the operation cost, it is possible to achieve a great practical effect such that it becomes possible to make a plan for installing the water treatment facility.

The present invention is not limited to the above embodiment. For example, a server having an estimation function such as the databases 1 and 2, the facility construction unit 4, and the installation cost estimation unit 5 is prepared, and the server is accessed from a terminal such as a personal computer through a communication line such as the Internet to perform water treatment. It can also be configured to perform a quotation process for the equipment. In this case, only the functions of the condition input unit 3 and the information presenting unit 6 (for example, a keyboard and a display) need to be provided as the terminal, and the usability of the estimation system can be improved. It is of course possible to incorporate the above-mentioned estimation system into the personal computer itself.

Although the water treatment equipment is constructed using the units of A, B, C, D and S types described above, it is also possible to use units of other specifications. The size (specification) of each unit is sufficient if it can be mounted in, for example, a truck / container, and the size is not particularly limited. In addition, the present invention can be variously modified and implemented without departing from the scope of the invention.

[0036]

As described above, according to the present invention, a water treatment unit required for constructing a water treatment facility that meets the required water treatment specifications is selected, and the water constructed using the unit is selected. Since the price of the treatment equipment (equipment price and operating price) can be easily estimated, the installation plan can be easily created when the water treatment equipment is temporarily needed in various factories or plants. The practically great effect can be obtained.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a water treatment facility estimation system according to an embodiment of the present invention.

FIG. 2 is a diagram showing a flow of a schematic processing procedure in the estimation system shown in FIG.

FIG. 3 is a diagram showing a configuration example of a basic water treatment facility unit in which a plurality of types of component parts constituting the components of the water treatment facility are assembled in advance in accordance with predetermined facility specifications.

FIG. 4 is a diagram showing a configuration example of a unit additionally used in the water treatment facility unit shown in FIG.

FIG. 5 is a diagram showing an example of a basic system system of a water treatment facility constructed by using a plurality of units.

FIG. 6 is a diagram showing an example of an algorithm for selecting a unit according to water treatment specifications.

[Explanation of symbols]

1 unit database 2 parts database 3 Condition input section 4 Facility construction department (unit selection means) 5 Equipment cost estimation department (equipment price estimation means) 6 Information presentation section 7 Parts Replacement Plan Creation Department (Parts Replacement Plan Creation Means) 8 Operation cost estimation department (operation price estimation means)

Claims (4)

[Claims] 1. A water treatment equipment quotation system comprising one or a plurality of types of units, wherein the equipment specifications and equipment prices of a plurality of types of units in which a plurality of types of components are assembled according to predetermined equipment specifications are provided. A unit database storing therein, condition input means for inputting a water treatment specification, and selecting one or a plurality of units required to construct a water treatment facility matching the water treatment specification by searching the unit database. Unit selecting means for estimating the equipment price of the water treatment facility constructed by the unit selected by the unit selecting means by searching the unit database, and the unit selected by the unit selecting means The information presenting means for presenting the configuration of the water treatment facility constructed by Water treatment equipment estimate system according to claim. 2. The water treatment facility estimation system according to claim 1, further comprising: a parts database storing replacement conditions of the parts constituting each of the units and parts prices thereof, and searching the parts database. A part replacement plan creating means for creating a replacement plan for the constituent parts of the unit selected by the unit selecting means, and a means for outputting the part replacement plan created by the part replacement plan creating means via the information presenting means. A water treatment equipment estimation system comprising: 3. The water treatment equipment estimation system according to claim 2, further searching the parts database in accordance with the parts replacement plan prepared by the parts replacement plan creating means, and operating the water treatment equipment to operate. A water treatment equipment estimation system comprising an operating price estimation means for estimating a price. 4. The condition input means and the information presenting means are connected to a server including the unit database, the unit selecting means and the estimating means via a predetermined communication line. The water treatment equipment estimation system according to claim 1.