WO2014023137A1

WO2014023137A1 - Compression-type heat pump assisted distillation device and process

Info

Publication number: WO2014023137A1
Application number: PCT/CN2013/077862
Authority: WO
Inventors: 许松伟; 于星; 陆庆权; 沈贵文; 张�杰; 崔磊
Original assignee: 南通醋酸纤维有限公司
Priority date: 2012-08-06
Filing date: 2013-06-25
Publication date: 2014-02-13
Also published as: CN103566612B; CN103566612A

Abstract

Provided are a compression-type heat pump assisted distillation device and process. The device comprises: a feed evaporator (1), a feed steam compressor (2), a distillation column (3), a column top condensate cooler (4), and a reflux tank (5) that are sequentially connected through a pipeline. Further provided is a compression-type heat pump assisted distillation process, using steam at the top of the distillation column as a heat source for heating feedstock.

Description

Compressed heat pump rectification device and process technology

The invention belongs to the field of chemical separation process and energy-saving technology, and relates to a compression heat pump rectification device and a process. Background technique

In the chemical production process, the rectification process of solvent purification and separation is often involved. In the rectification process, the overhead vapor is usually directly condensed, part of the condensate is refluxed as a rectification column, and part is taken as a product. This process not only increases the cooling cycle water consumption, but also loses the condensation of the overhead steam. Latent heat. Compressed heat pump rectification processes such as external working type, tower kettle flashing or overhead vapor direct compression can be used to recover latent steam condensation overhead, such as propane-propylene separation and triphenyl separation.

Heat pump technology is a new energy technology that has received worldwide attention in recent years. A heat pump is a device that transfers thermal energy from a low temperature heat source to a high temperature heat source. As an effective tool for waste heat utilization, heat pump technology is gradually used in the field of chemical rectification. Supranto S. et al. studied the use of two-stage vapor compression, and the use of heat pump distillation in the rectification unit for separating ethanol and water (Heat pump assisted distillation. IX: Acceptance trials on a system for separating ethanol and water, International Journal Of Energy Research, 1988, 12, p 413-422 Gaspillo P. et al. introduced Dehydrogenation of 2-propanol in reactive distillation column for chemical heat pump (Dehydrogenation of 2-propanol in reactive distillation column for chemical heat pump, Journal of Chemical Engineering of Japan, 1998, 31, p440-444) _o Chinese Patent No. 200680023637.6 describes a rectification apparatus using a heat pump for rectifying a vaporizable component in an aqueous mixture.

Chinese patent 200810231613.0 introduces a diethyl carbonate heat pump rectification device and a process, and introduces the steam material at the top of the rectification column into a compressor to be used as a heat source for the refiller of the column. Deng Renjie et al. studied the new process of butyl acetate heat pump distillation (Chemical Engineering, 2006, issue 6). In view of the high energy consumption of the conventional butyl acetate production process, it is proposed to apply heat pump distillation to the production of butyl acetate to develop acetic acid. New process for butyl ester heat pump distillation. The process also compresses the vapor at the top of the column and uses it for the heat source of the column reboiler. The temperature difference between the column of the esterification column and the distillation column in the apparatus is 13 °C and 18 °C, respectively.

The heat pump technology is applied to the rectification process in the chemical industry. When the temperature difference of the top column of the distillation column is large (especially when it is greater than 30 ° C), if the above heat pump rectification process is adopted, the compression ratio is very high, resulting in compression. The power of the machine is improved, the energy saving effect is not obvious, and the energy utilization is insufficient. Summary of the invention In order to solve the heat pump rectification process in the chemical industry, when the temperature difference of the top of the distillation column tower is large (especially when it is greater than 30 ° C), the compression ratio is very high, the energy saving effect is not obvious, and the energy utilization is insufficient; It is an object of the present invention to provide a compression heat pump rectification apparatus.

Another object of the present invention is to provide a compression heat pump rectification process.

The technical solution of the present invention is as follows:

SUMMARY OF THE INVENTION The present invention provides a compression heat pump rectification apparatus comprising a feed evaporator, a feed steam compressor, a rectification column, an overhead condensing cooler, and a reflux tank, which are in turn connected by piping.

The feed evaporator is provided with a feed evaporator feed port, a feed evaporator discharge port, a feed evaporator heating medium feed port, and a feed evaporator heating medium discharge port, and a feed evaporator The heating medium feed port is located at the side of the feed evaporator, and the feed evaporator heating medium discharge port is located at the other side corresponding to the feed evaporator heating medium feed port; the feed evaporator discharge port and the compression The feed inlet of the machine is connected, the heating medium discharge port of the feed evaporator is connected with the inlet of the overhead condensing cooler, and the feed medium of the feed evaporator is connected with the steam outlet of the top of the distillation column.

The feed steam compressor is provided with a compressor feed port and a compressor discharge port, and the compressor feed port is connected with the feed evaporator discharge port, and the compressor discharge port is connected with the rectification column feed port. .

The rectification column is provided with a rectification column feed port, a rectification column overhead steam outlet, a rectification column tower cavage outlet and a reflux liquid feed port, and the rectification column feed port is located at the side of the rectification column In the middle side, the reflux feed port is located on the other side corresponding to the rectification column feed port, the rectification column overhead steam outlet is located at the top of the rectification column, and the rectification column bottom coke outlet is located at the bottom of the rectification column The distillation column feed port is connected to the compressor discharge port, the distillation column top steam outlet is connected to the feed evaporator heating medium feed port, and the reflux liquid feed port is connected to the reflux liquid outlet.

The tower top condensing cooler is provided with a cooler inlet and a cooler outlet, and the cooler inlet is connected with the feed evaporator heating medium outlet, and the cooler outlet and the return tank are fed. Port connection.

The reflux tank is provided with a return tank inlet, a reflux outlet and a top product outlet, and the reflux tank inlet is connected to the cooler outlet, and the reflux outlet is connected to the reflux inlet.

The invention also provides a compression heat pump rectification process, the process comprising the following steps:

First, the organic mixed solution to be separated is added to the feed evaporator, and the feed evaporator is heated under reduced pressure with the top steam of the distillation column as a heat source to completely vaporize the feed, and the vaporized feed is fed. After the steam compressor is compressed to increase the feed pressure, it enters the rectification column; after the rectification of the rectification column is completed, the liquid in the rectification column reaches the production standard and is directly produced, and the steam at the top of the column is passed to the feed evaporator as The heat source performs heat exchange, and the overhead steam and part of the condensate after the heat exchange enters the overhead condensing cooler to be condensed into a liquid into the reflux tank; the condensate portion of the reflux tank is passed to the rectification column to continue to reflux, and the rest is taken as a product.

The organic mixed solution is a mixture of an organic compound and water or a mixture of two organic compounds.

The organic compound is selected from the group consisting of an alcohol, a ketone, an aldehyde or an ester organic compound, for example: methanol, ethanol, and n-propyl Alcohol, isopropanol, formaldehyde, acetaldehyde, propionaldehyde, acetone, methyl ethyl ketone, methyl formate or ethyl formate.

The organic mixed solution has a light component mass concentration of 25 to 75%.

The feed evaporator is selected from the group consisting of a plate heat exchanger, a tube heat exchanger, a tube plate heat exchanger or a spiral plate heat exchanger, and the heat exchange temperature difference ranges from 10 to 60 °C.

The feed steam compressor is selected from the group consisting of a positive displacement compressor, a reciprocating compressor, and a centrifugal compressor, and has a temperature rise range of 20 to 60 ° C and a compression ratio of 1.5 to 5.0.

The rectification column is selected from the group consisting of a sieve tray tower, a float valve tower or a packed tower, and the reflux ratio of the column top is 1.0 to 5.0.

Compared with the prior art, the present invention has the following advantages and beneficial effects:

1. The present invention discloses a novel heat pump rectification process for rectification of a large temperature difference (greater than 30 ° C) in a column tower. The steam at the top of the rectification column is used as a heat source for heating the feed, and the feed can be heated not only to the feed. Dew point or above, and significantly reduce the compression ratio of the overhead steam, reducing compression power consumption, thereby reducing energy consumption.

2. The present invention can greatly reduce the required cooling cycle water consumption of steam condensation at the top of the tower by recovering the latent heat of condensation of the steam at the top of the tower and effectively increasing the heat utilization efficiency.

3. The invention is applicable to all heat pump rectification processes satisfying the conditions, and has a wide application range.

4. The present invention relates to a novel compression heat pump rectification process for a temperature difference of a tower overhead tank exceeding 30 °C. The process uses the steam at the top of the distillation column as a heat source, and the steam at the top of the column is condensed while heating the feed to a vaporization condition under reduced pressure. The vaporized feed is compressed by the compressor and passed to the rectification column. Compared with the existing rectification technology, if the prior art rectification column uses a gas phase feed heated by an external heat source, the present invention saves the heat consumed by the vaporization of the feedstock; if the prior art rectification column is a liquid phase feed The invention transforms the rectification column into a gas phase feed, and the energy consumption required for the rectification process is greatly saved due to the increase of the feed energy. For the distillation process with large temperature difference between the top and bottom of the conventional distillation column, not only the cooling cycle water consumption for the steam at the top of the condensation tower but also the latent heat of condensation of the top steam can be recovered, and the heat utilization efficiency can be improved, and the energy consumption can be reduced. DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a flow chart showing the heat pump rectification process of the embodiment of the present invention.

1 is feed evaporator, 2 is feed steam compressor, 3 is rectification tower, 4 is tower top condensation cooler, 5 is reflux tank, 11 is feed evaporator inlet, 12 is feed evaporator The discharge port, 13 is the feed evaporator heating medium feed port, 14 is the feed evaporator heating medium discharge port, 21 is the compressor feed port, 22 is the compressor discharge port, and 31 is the rectification column. The feed port, 32 is the steam outlet of the distillation column overhead, 33 is the distillation column, the steam recovery outlet, 34 is the reflux feed inlet, 41 is the cooler feed port, 42 is the cooler discharge port, 51 is the reflux The tank feed port, 52 is the reflux liquid outlet, and 53 is the top product production outlet.

Fig. 2 is a flow chart showing the conventional rectification process of Comparative Example 1.

6 is a feed evaporator, 7 is a rectification column, 8 is a column top condensation cooler, and 9 is a reflux tank. detailed description

The invention will be further described below in conjunction with the embodiments shown in the drawings.

Example 1

The process of the heat pump rectification process of the 50 wt% methanol-water solution separation process is shown in Fig. 1. Fig. 1 is a flow chart showing the heat pump rectification process according to the embodiment of the present invention; the rectification column adopts a gas phase feed.

According to the feed amount of 10T / h, the feed temperature is 50 ° C calculation, the distillation column 3 uses 45 actual trays, the reflux ratio of the top of the tower is 3.0, the steam from the top of the distillation tower 3 is used as the feed evaporator The heat source of 1 is heated under reduced pressure to vaporize the feed, and then pressurized by the feed steam compressor 2 to increase the feed pressure and then enter the rectification column 3. At the top of the rectification column 3, methanol having a water content of less than 100 ppm is obtained, and the methanol concentration in the column reactor is also less than 100 ppm. The overhead vapor after heat exchange through the feed evaporator 1 is cooled to a liquid phase in the overhead condensing cooler 4, and the heat exchange amount is 1.38 Gcal/h. The heat loss of the rectification column 3 column kettle reboiler is 1.55 Gcal/h. The overhead condensing cooler 4 condensed liquid enters the reflux tank 5; the condensate portion of the reflux tank 5 is passed to the rectification column 3 to continue the reflux, and the rest is taken as a product.

Comparative example 1

The 50 wt% methanol-water solution separation process is shown in Figure 2. The rectification column uses a gas phase feed with a feed rate of ΙΟΤ/h and a feed temperature of 50 °C.

The rectification process uses 45 actual trays, and the reflux ratio of the rectification column 7 is 3.0, and the methanol at the top of the column is less than 100 ppm, and the methanol concentration in the column is also less than 100 ppm. According to the feed amount of 10 T/h and the feed temperature of 50 ° C, the heat required for the feed evaporator 6 to heat the feed to gasification was 4.43 Gcal/h. The overhead condenser cooler 8 has a cooling capacity of 5.20 Gcal/h. The heat loss of the 7 column kettle reboiler is 1.55 Gcal/h.

Example 1 Compared with Comparative Example 1, the feed steam compressor 2 compresses the feed steam from about 0.3 Bar to 1.3 Bar (compression ratio 4.3), and the required effective shaft power is 793 KW, which is calculated according to the motor efficiency of 0.7. The increased power consumption is 1135 kW, which is 0.98 Gcal/h. The entire process saves heating energy consumption 4.43Gcal/h, saving cooling energy consumption 3.82Gcal/h, saving 7.27Gcal/h.

Example 2

25wt% ethanol-water solution separation process The heat pump rectification process is shown in Figure 1, and the rectification column uses gas phase feed. According to the feed amount of 10T / h, the feed temperature is 50 ° C calculation, the distillation column 3 uses 23 actual trays, the reflux ratio of the top of the tower is 5.0, the steam from the top of the distillation tower 3 is used as the feed evaporator The heat source of 1 is heated under reduced pressure to vaporize the feed, and then pressurized by the feed steam compressor 2 to increase the feed pressure and then enter the rectification column 3. At the top of the rectification column 3, ethanol having a water content of less than 15% by weight is obtained, and the ethanol concentration of the column is less than 0.5% by weight. The overhead vapor after heat exchange by the feed evaporator 1 is cooled to a liquid phase in the overhead condensing cooler 4, and the heat exchange amount is 0.28 G _C al/h. The heat loss of the rectification column 3 column refiller was 0.49 G _C al/h. The liquid condensed by the overhead condensing cooler 4 enters the reflux tank 5; the condensate portion of the reflux tank 5 is passed to the rectification column 3 to continue the reflux, and the remainder is produced as a product. Comparative example 2

The 25 wt% ethanol-water solution separation process is shown in Figure 2. The rectification column uses a gas phase feed with a feed rate of ΙΟΤ/h and a feed temperature of 50 °C.

The rectification process uses 23 actual trays, the rectification column 7 operates at a reflux ratio of 5.0, the top of the column obtains ethanol having a water content of less than 15 wt%, and the column kettle produces an ethanol concentration of less than 0.5 wt%. The heat required for the feed evaporator 6 to heat the feed to gasification was 5.07 Gcal/h, based on the feed amount of 10 T/h and the feed temperature of 50 °C. The overhead condensing cooler 8 has a cooling capacity of 5.17 Gcal/h. The heat loss of the rectification tower crucible reboiler was 0.49 G _C al/h.

Example 2 Compared with Comparative Example 2, the feed steam compressor 2 compresses the feed steam from about 0.3 Bar to 1.5 Bar (compression ratio 5.0), and the required effective shaft power is 1050 KW, which is calculated according to the motor efficiency of 0.7. The increased power consumption is 1500 KW, which is 1.29 Gcal/h. The entire process saves heating energy consumption by 5.07Gcal/h, saving cooling energy consumption by 4.89Gcal/h, and saving 8.67Gcal/h.

Example 3

The process of the heat pump rectification process of the 75 wt% acetone-water solution separation process is shown in Fig. 1, and the rectification column uses the gas phase feed. According to the feed amount of 10T / h, the feed temperature is 50 ° C calculation, the distillation column 3 uses 28 actual trays, the reflux ratio of the top of the tower is 1.5, the steam from the top of the distillation tower 3 is used as the feed evaporator The heat source of 1 is heated under reduced pressure to vaporize the feed, and then pressurized by the feed steam compressor 2 to increase the feed pressure and then enter the rectification column 3. At the top of the rectification column 3, acetone having a water content of less than 3% by weight is obtained, and the acetone concentration of the column is less than 1% by weight. The overhead vapor after heat exchange by the feed evaporator 1 is cooled to a liquid phase in the overhead condensing cooler 4, and the heat exchange amount is 0.31 G _{C a} /h. The heat loss of the rectification column 3 column kettle reboiler was 0.37 G _C al/h. The liquid condensed by the overhead condensing cooler 4 enters the reflux tank 5; the condensate portion of the reflux tank 5 is passed to the rectification column 3 to continue the reflux, and the remainder is produced as a product.

Comparative example 3

The 75 wt% acetone-water solution separation process is shown in Figure 2. The rectification column uses a gas phase feed with a feed rate of ΙΟΤ/h and a feed temperature of 50 °C.

The rectification process uses 28 actual trays, the rectification column 7 operates at a reflux ratio of 1.5, the top of the column obtains acetone having a water content of less than 3 wt%, and the column kettle produces an acetone concentration of less than 1 wt%. Based on the feed amount of 10 T/h and the feed temperature of 50 ° C, the heat required for the feed evaporator 6 to heat the feed to gasification was 2.63 Gcal/h. The overhead condensing cooler 8 has a cooling capacity of 2.79 Gcal/h. The heat loss of the rectification column 7 column kettle reboiler was 0.37 G _C al/h.

Example 3 Compared with Comparative Example 3, the feed steam compressor 2 compresses the feed steam from about 0.35 Bar to 1.3 Bar (compression ratio 3.7), and the required effective shaft power is 620 KW, which is calculated according to the motor efficiency of 0.7. The increased power consumption is 886 kW, which is 0.76 Gcal/h. The entire process saves heating energy consumption 2.63Gcal/h, saving cooling energy consumption 2.48Gcal/h, saving a total of 4.35Gcal/h.

Example 4 As shown in Fig. 1, Fig. 1 is a flow chart showing the heat pump rectification process of the embodiment of the present invention.

A compression heat pump rectification apparatus comprising a feed evaporator 1, a feed steam compressor 2, a rectification column 3, a column top condensing cooler 4, and a reflux tank 5, which are sequentially connected through a pipeline.

The feed evaporator 1 is provided with a feed evaporator feed port 11, a feed evaporator discharge port 12, a feed evaporator heating medium feed port 13 and a feed evaporator heating medium discharge port 14, feeding The evaporator heating medium feed port 13 is located at the side of the feed evaporator 1, and the feed evaporator heating medium discharge port 14 is located at the other side corresponding to the feed evaporator heating medium feed port 13; The discharge port 12 is connected to the compressor feed port 21, and the feed evaporator heating medium discharge port 14 is connected to the overhead condensing cooler feed port 41. The feed evaporator heats the medium feed port 13 and the rectification column. The overhead steam outlet 32 is connected.

The feed steam compressor 2 is provided with a compressor feed port 21 and a compressor discharge port 22, and the compressor feed port 21 is connected to the feed evaporator discharge port 12, the compressor discharge port 22 and the rectification column The feed port 31 is connected.

The rectification column 3 is provided with a rectification column feed port 31, a rectification column overhead steam outlet 32, a rectification column bottom coke outlet 33 and a reflux feed port 34, and the rectification column feed port 31 is located in the rectification column In the middle of the side of the column 3, the reflux feed port 34 is located on the other side corresponding to the rectification column feed port 31, and the rectification column overhead vapor outlet 32 is located at the top of the rectification column 3, and the rectification column bottoms The production outlet 33 is located at the bottom of the rectification column 3; the rectification column feed port 31 is connected to the compressor discharge port 22, and the rectification column overhead steam outlet 32 is connected to the feed evaporator heating medium feed port 13, the reflux liquid The feed port 34 is connected to the reflux outlet 52.

The tower top condensing cooler 4 is provided with a cooler feed port 41 and a cooler discharge port 42, and the cooler feed port 41 is connected to the feed evaporator heating medium discharge port 14, the cooler discharge port 42 and the reflux The tank feed port 51 is connected.

The return tank 5 is provided with a return tank inlet port 51, a reflux liquid outlet 52 and an overhead product outlet port 53, and the return tank inlet port 51 is connected to the cooler discharge port 42, the reflux liquid outlet 52 and the reflux liquid feed port. 34 connections.

The above description of the embodiments is intended to facilitate the understanding and application of the present invention by those skilled in the art. It will be obvious to those skilled in the art that various modifications can be made to these embodiments and the general principles described herein can be applied to other embodiments without the inventive work. Therefore, the present invention is not limited to the embodiments herein, and those skilled in the art, in light of the present invention, the modifications and modifications may be made without departing from the scope of the invention.

Claims

A compression heat pump rectification apparatus, characterized in that the apparatus comprises a feed evaporator (1), a feed steam compressor (2), a rectification column (3), a column top condensation cooler (4) And the return tank (5), which is connected in turn through the pipeline.

2. The compression heat pump rectification apparatus according to claim 1, wherein: the feed evaporator (1) is provided with a feed evaporator inlet (11), and a feed evaporator discharge. Port (12), feed evaporator heating medium feed port (13) and feed evaporator heating medium discharge port (14), feed evaporator heating medium feed port (13) located in feed evaporator (1) The side of the feed evaporator heating medium discharge port (14) is located on the other side of the feed evaporator heating medium feed port (13); the feed evaporator discharge port (12) and compression The machine feed port (21) is connected, the feed evaporator heating medium discharge port (14) is connected to the overhead condensing cooler feed port (41), the feed evaporator heating medium feed port (13) and the rectification The tower top steam outlet (32) is connected.

3. The compression heat pump rectification apparatus according to claim 1, wherein said feed steam compressor (2) is provided with a compressor feed port (21) and a compressor discharge port (22). ), compressor feed port (21) and feed evaporator discharge port

(12) Connection, compressor discharge port (22) is connected to the distillation column inlet (31).

4. The compression heat pump rectification apparatus according to claim 1, wherein: the rectification column (3) is provided with a rectification column feed port (31) and a rectification column overhead steam outlet ( 32), the distillation column tower recovery port (33) and the reflux liquid feed port (34), the rectification column feed port (31) is located in the middle of the side of the rectification column (3), and the reflux liquid feed port ( 34) On the other side of the rectification column feed port (31), the rectification column overhead steam outlet (32) is located at the top of the rectification column (3), and the rectification column tower is taken at the outlet (33) Located at the bottom of the rectification column (3); the rectification column feed port (31) is connected to the compressor discharge port (22), the rectification column overhead steam outlet (32) and the feed evaporator heating medium feed port (13) connection, return inlet

(34) Connect to the return outlet (52).

5. The compression heat pump rectification apparatus according to claim 1, wherein said overhead condensing cooler (4) is provided with a cooler feed port (41) and a cooler discharge port (42). The cooler feed port (41) is connected to the feed evaporator heating medium discharge port (14), and the cooler discharge port (42) is connected to the return tank feed port (51).

6. The compression heat pump rectification apparatus according to claim 1, wherein: the return tank (5) is provided with a return tank inlet port (51), a reflux liquid outlet (52), and a top product. The recovery port (53), the return tank inlet (51) is connected to the cooler discharge port (42), and the reflux outlet (52) is connected to the reflux feed port (34).

7. The compression heat pump rectification process carried out by the apparatus according to any one of claims 1 to 6, wherein the process comprises the steps of:

First, the organic mixed solution to be separated is added to the feed evaporator (1), and the feed evaporator (1) is heated to a complete temperature under reduced pressure using the distillation column (3) overhead steam as a heat source. After vaporization, the vaporized feed is fed to the rectification column (3) by the feed steam compressor (2) to increase the feed pressure; after the rectification (3) rectification, the rectification column (3) The liquid in the kettle reaches the production standard and is directly produced. The steam at the top of the column is fed into the feed evaporator (1) as a heat source for heat exchange. After heat exchange. The overhead steam and part of the condensate enter the overhead condensing cooler (4) and condense into a liquid into the reflux tank (5); the condensate in the reflux tank (5) is passed to the rectification column (3) to continue the reflux, and the rest as a product Produced.

The compression heat pump rectification process according to claim 7, wherein the organic mixed solution is a mixture of an organic compound and water or a mixture of two organic compounds.

9. The compression heat pump rectification process according to claim 8, wherein: the organic compound is selected from the group consisting of an alcohol, a ketone, an aldehyde or an ester organic compound, for example: methanol, ethanol, n-propanol, and different Propanol, formaldehyde, acetaldehyde, propionaldehyde, acetone, methyl ethyl ketone, methyl formate or ethyl formate.

10. The compression heat pump rectification process according to claim 7, wherein: the organic mixed solution has a light component mass concentration of 25 to 75%.

11. The compression heat pump rectification process according to claim 7, wherein: the feed evaporator (1) is selected from the group consisting of a plate heat exchanger, a tube heat exchanger, a tube plate heat exchanger or a spiral One of the plate heat exchangers, the heat transfer temperature difference ranges from 10 to 60 ° C o

12. The compression heat pump rectification process according to claim 7, wherein: the feed steam compressor (2) is selected from the group consisting of a positive displacement compressor, a reciprocating compressor, and a centrifugal compressor. The temperature range is 20~60°C, and the compression ratio is 1.5~5.0.

The compression heat pump rectification process according to claim 7, characterized in that: the rectification column (3) is selected from one of a sieve tray tower, a float valve tower or a packed tower, and the reflux ratio of the column top It is 1.0~5.0.