CN210261721U

CN210261721U - Quantitative water adding device

Info

Publication number: CN210261721U
Application number: CN201921085230.7U
Authority: CN
Inventors: 邹旭; 袁建平; 刘勇
Original assignee: Sichuan Yibin Minjiang Mechinery Manufacturing Co ltd
Current assignee: Sichuan Yibin Minjiang Mechinery Manufacturing Co ltd
Priority date: 2019-07-11
Filing date: 2019-07-11
Publication date: 2020-04-07
Anticipated expiration: 2029-07-11

Abstract

The utility model discloses a quantitative water adding device, belonging to the technical field of white spirit brewing, which specifically comprises a flow detection unit, a control unit, a water outlet pipeline, a water storage device and a water adding device; the output end of the flow detection unit is connected with the control unit, arranged on the water outlet pipeline and used for detecting the flow of hot water; one end of the water outlet pipeline is connected with the bottom of the water storage device through a fourth flange ball valve, and the other end of the water outlet pipeline is connected with the water adding device. The flow detection unit comprises a flow meter, the water storage device comprises a high-level water tank, and the water adding device comprises a water adding gun. The utility model discloses a flow of flowmeter detection water, through the rifle that adds water add water, realized that the ration adds water, further improved the security of adding water in the white spirit brewing technology.

Description

Quantitative water adding device

Technical Field

The utility model relates to a white spirit makes technical field, especially relates to a ration device of adding water.

Background

The white spirit is a special distilled spirit made up by using grain as main raw material, using Daqu, Xiaoqu or bran koji and yeast as saccharification leaven and through the processes of cooking, saccharifying, fermenting and distilling. In the white spirit brewing industry, quantitative and accurate water addition is needed in the processes of distillation and retort discharge. But the white spirit on the market at present is made and is added water installation still can not realize the ration and add water operation, needs the manual work to measure and add water, adds water at distillation, the rice steamer technology of going out through this kind of mode, and staff's intensity of labour is big, and adds water inefficiency, still causes the spilling of water easily at the volume water in-process that adds, and the volume of adding water that leads to is inaccurate, very easily influences the quality of white spirit. Furthermore, because the water in the processes of distilling the white spirit and discharging the white spirit from the steamer is boiled water with the temperature of 100 ℃, workers are easily scalded and have low safety when adding water by using tools such as a barrel and the like.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the problem that can't realize adding water, artifical adding water security low among the prior art, provide a ration water installation.

The purpose of the utility model is realized through the following technical scheme: a quantitative water adding device comprises a flow detection unit, a control unit, a water outlet pipeline, a water storage device and a water adding device; the output end of the flow detection unit is connected with the control unit, arranged on the water outlet pipeline and used for detecting the flow of hot water; one end of the water outlet pipeline is connected with the bottom of the water storage device, and the other end of the water outlet pipeline is connected with the water adding device.

Specifically, the flow detection unit comprises a flowmeter, the water storage device comprises a high-level water tank, and the water adding device comprises a water adding gun.

Specifically, the water outlet pipeline comprises a first water outlet pipeline and a second water outlet pipeline, and the first water outlet pipeline is connected with the second water outlet pipeline in an inverted T shape; the first water outlet pipeline comprises an eighth seamless pipeline, the second water outlet pipeline comprises a ninth seamless pipeline and a tenth seamless pipeline, the water inlet end of the eighth seamless pipeline is connected with the high-level water tank through a fourth flange ball valve, and the water outlet end of the eighth seamless pipeline is connected with the water inlet end of the ninth seamless pipeline and the water inlet end of the tenth seamless pipeline.

Specifically, a fifth flange ball valve, a first flowmeter and a first electric ball valve are sequentially arranged at the water inlet end of the ninth seamless pipeline, and a seventh flange ball valve, a second flowmeter and a second electric ball valve are sequentially arranged at the water inlet end of the tenth seamless pipeline.

The device further comprises a collecting box, wherein the collecting box is connected with the high-level water tank through a first water inlet pipeline, one end of the first water inlet pipeline is connected to the bottom of the collecting box, and the other end of the first water inlet pipeline is connected to the top of the high-level water tank.

Specifically, a hot water pump is arranged on the first water inlet pipeline and used for conveying hot water in the collecting tank to the high-level water tank.

Specifically, the device still includes the ice bucket, and first ice bucket is connected with the collecting box through the second inlet channel, and the second ice bucket is connected with the collecting box through the third inlet channel.

Specifically, the device further comprises a water level detection unit, wherein the output end of the water level detection unit is connected with the control unit, arranged on the collection box and the high-level water tank and used for detecting the water levels of the collection box and the high-level water tank.

Specifically, the device further comprises a temperature detection unit, wherein the output end of the temperature detection unit is connected with the control unit, is arranged inside the high-level water tank and is used for detecting the temperature of water in the high-level water tank.

Specifically, the device further comprises an alarm unit arranged outside the high-level water tank, wherein the alarm unit is connected with the output end of the control unit and used for receiving a control instruction of the control unit and executing a corresponding alarm action.

Compared with the prior art, the utility model discloses beneficial effect is:

the utility model discloses a hot water flow of output among the flowmeter detection high water tank exports to the hot water rifle through flange ball valve and the electric ball valve control ration hot water of locating second outlet conduit, realizes the action of adding water of ration through the hot water rifle.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the figure:

fig. 1 is a schematic view of embodiment 1 of the present invention;

fig. 2 is a schematic view of a second outlet conduit method in embodiment 1 of the present invention;

FIG. 3 is a schematic diagram of the circuit control principle of the present invention;

FIG. 4 is a schematic diagram of the circuit control principle of the present invention;

FIG. 5 is a schematic diagram of the circuit control principle of the present invention;

FIG. 6 is a schematic diagram of the circuit control principle of the present invention;

fig. 7 is a schematic diagram of the circuit control principle of the present invention.

In the figure: the device comprises a first ice bucket 1, a second ice bucket 2, a first flange ball valve 3, a second flange ball valve 4, a first seamless pipeline 5, a second seamless pipeline 6, a collecting box 7, a first liquid level meter 8, a hot water pump 9, a third seamless pipeline 10, a high-level water tank 11, a fourth seamless pipeline 12, a fifth seamless pipeline 13, a first flange stop valve 14, a second flange stop valve 15, a third flange stop valve 16, a fourth flange stop valve 17, a thermal resistor 18, an alarm 19, a second liquid level meter 20, a third flange ball valve 21, a sixth seamless pipeline 22, a seventh seamless pipeline 23, a fourth flange ball valve 24, an eighth seamless pipeline 25, a heat preservation device 26, a fifth flange ball valve 28, a first flow meter 29, a first electric ball valve 30, a sixth flange ball valve 31, a seventh flange ball valve 34, a second flow meter 35, a second electric ball valve 36, an eighth flange ball valve 37, a first water adding gun 39, a water gun 30, a water gun, A second water adding gun 40, a ninth flanged ball valve 41, a ninth seamless pipeline 42, a tenth seamless pipeline 43, an eleventh seamless pipeline 44 and a twelfth seamless pipeline 45

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like are the directions or positional relationships indicated on the basis of the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element indicated must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Furthermore, the technical features mentioned in the different embodiments of the invention described below can be combined with each other as long as they do not conflict with each other.

Example 1

As shown in fig. 1, in embodiment 1, a quantitative water adding device specifically includes a flow detection unit, a control unit, a water level detection unit, a temperature detection unit, an alarm unit, a water inlet pipe, a water outlet pipe, a water storage device, a water adding device, a collection tank 7, and an ice bucket. Specifically, the output end of the flow detection unit is connected with the control unit and arranged on the water outlet pipeline; the output end of the water level detection unit is connected with the control unit and is arranged on the collecting box 7 and the water storage device; the output end of the temperature detection unit is connected with the control unit and arranged on the water storage device; the alarm unit is connected with the output end of the control unit and arranged on the water storage device; the ice bucket comprises a first ice bucket 1 and a second ice bucket 2, the first ice bucket 1 is in threaded connection with the collecting box 7 through a second water inlet pipeline, and the second ice bucket 2 is in threaded connection with the collecting box 7 through a third water inlet pipeline; the collecting tank 7 is in threaded connection with the water outlet device through a first water inlet pipeline, one end of the first water inlet pipeline is connected to the bottom of the collecting tank 7, and the other end of the first water inlet pipeline is connected to the top of the water storage device; one end of the water outlet pipeline is in threaded connection with the bottom of the water storage device through a fourth flange ball valve 24, and the other end of the water outlet pipeline is in threaded connection with the water adding device.

It should be noted that the water inlet pipe, the water outlet pipe and other seamless pipes are all in threaded connection in this embodiment, and because the connection between the pipes and the devices (the water storage device, the collecting box 7 and the ice bucket) belong to the prior art, the details are not described herein.

Further, the control unit is arranged in the shell, and the shell is made of materials including but not limited to aluminum and aluminum alloy, has a waterproof function, and has a protection effect on the control unit.

Further, the control unit in this embodiment includes, but is not limited to, a single chip microcomputer, and a programmable logic controller, the flow rate detection unit includes, but is not limited to, a flow meter, the water level detection unit includes, but is not limited to, a floating ball, and a water level gauge, the temperature detection unit includes, but is not limited to, a temperature sensor and/or a thermal resistor 18, the alarm unit includes, but is not limited to, an LED lamp and a buzzer, the water storage device includes, but is not limited to, a head tank 11, and.

As an option, the control unit in this embodiment is specifically siemens S7-200PLC, the flow detection unit is specifically a flow meter electromagnetic flow meter, the water level detection unit is specifically a water level meter magnetic flap level meter, the temperature detection unit is specifically a thermal resistor, and the alarm unit is specifically an audible and visual alarm lamp.

Further, the ice bucket includes first ice bucket 1 and second ice bucket 2, and first ice bucket 1 is connected with collecting box 7 through the second inlet channel, and second ice bucket 2 is connected with collecting box 7 through the third inlet channel. Specifically, the top of first ice bucket 1 is connected to second inlet channel one end, and the top of collecting box 7 is connected to the other end, and the top of first ice bucket 1 is connected to third inlet channel one end, and the top of collecting box 7 is connected to the other end. In order to condense the wine vapor into liquid wine, it is necessary to continuously add cooling water into the ice bucket and discharge hot water, and the water with the highest temperature in the ice bucket is the water on the upper layer of the top of the ice bucket, so that cold water is added into the middle lower part of the ice bucket, and hot water is discharged from the upper part. Furthermore, the first flange ball valve 3 is arranged on the second water inlet pipeline, the second flange ball valve 4 is arranged on the third water inlet pipeline, the first flange ball valve 3 and the second flange ball valve 4 manually control whether to convey hot water in the ice bucket to the collecting box 7, namely when the water amount in the collecting box 7 is large, a worker manually closes the first flange ball valve 3 and the second flange ball valve 4 to prevent more hot water from entering the collecting box 7, and when the water amount in the collecting box 7 is small, the worker opens the first flange ball valve 3 and the second flange ball valve 4 to convey the water in the ice bucket to the collecting box 7. Wherein, the second inlet conduit is specifically the first seamless pipeline 5, and the third inlet conduit is specifically the second seamless pipeline 6.

Further, the collecting box 7 is connected with the high level water tank 11 through a first water inlet pipeline, one end of the first water inlet pipeline is connected to the bottom of the collecting box 7, and the other end of the first water inlet pipeline is connected to the top of the high level water tank 11. Specifically, a hot water pump 9 is arranged on the first water inlet pipeline and used for conveying hot water in the collecting tank 7 to the high-level water tank 11. Wherein the first water inlet pipe is specifically a third seamless pipe 10. The collecting box 7 is also provided with a first liquid level meter 8, one end of the first liquid level meter 8 is connected to the top of the high-level water tank 11 through a seamless pipeline, and the other end of the first liquid level meter is connected to the bottom of the collecting box 7 through a seamless pipeline and used for detecting the water level change in the collecting box 7. Wherein, the first liquid level meter 8 is a magnetic turning plate liquid level meter with a remote transmission function LI 1101.

Further, the high-level water tank 11 is connected with a water adding gun through an output pipeline. Specifically, the water outlet pipeline comprises a first water outlet pipeline and a second water outlet pipeline, and the first water outlet pipeline is connected with the second water outlet pipeline in an inverted T shape; the first water outlet pipeline comprises an eighth seamless pipeline 25, the second water outlet pipeline comprises a ninth seamless pipeline 42 and a tenth seamless pipeline 43, the water inlet end of the eighth seamless pipeline 25 is in threaded connection with the bottom of the high-level water tank 11, and the water outlet end of the eighth seamless pipeline 25 is fixedly connected with the water inlet end of the ninth seamless pipeline 42 and the water inlet end of the tenth seamless pipeline 43 through large and small heads. More specifically, a fifth flange ball valve 28, a first flow meter 29 and a first electric ball valve 30 are sequentially arranged at a water inlet end of the ninth seamless pipe 42, and a seventh flange ball valve 34, a second flow meter 35 and a second electric ball valve 36 are sequentially arranged at a water inlet end of the tenth seamless pipe 43, that is, hot water output from the high-level water tank 11 needs to be output to the first water adding gun 39 through the fifth flange ball valve 28 and the first electric ball valve 30, or hot water output from the high-level water tank 11 needs to be output to the second water adding gun 40 through the seventh flange ball valve 34 and the second electric ball valve 36. Wherein, the first water adding gun 39 is in threaded connection with a ninth seamless pipeline 42 through a screw head, and the second water adding gun 40 is in threaded connection with a tenth seamless pipeline 43 through a screw head.

Furthermore, the second water outlet pipe further comprises an eleventh seamless pipe 44 and a twelfth seamless pipe 45, one end of the eleventh seamless pipe 44 is connected between the water inlet end of the ninth seamless pipe 42 and the fifth flanged ball valve 28, and the other end is connected to the first water adding gun 39 through a screw head; one end of the twelfth seamless pipeline 45 is connected between the water inlet end of the tenth seamless pipeline 43 and the seventh flanged ball valve 34, and the other end is connected to the second water adding gun 40 through a screw head. The eleventh seamless pipeline 44 is further provided with a sixth flange ball valve 31, the twelfth seamless pipeline 45 is further provided with an eighth flange ball valve 37, and non-quantitative water adding can be realized by opening the sixth flange ball valve 31 and/or the eighth flange ball valve 37.

Furthermore, the eighth seamless pipe 25 is coated with heat insulating materials, including but not limited to rock wool and high temperature resistant glass wool, for ensuring that the water output from the high-level water tank 11 is 100 ℃, and further ensuring the process and quality of brewing white spirit. More specifically, the eighth seamless pipe 25 is further provided with a fourth flange ball valve 24, and the fourth flange ball valve 24 is a manual valve, and hot water in the high-level water tank 11 can be output by manually unscrewing the valve.

Furthermore, the high-level water tank 11 is also provided with a thermal resistor, the hot end of the thermal resistor is arranged in the hot water in the high-level water tank 11, and the free end of the thermal resistor is exposed in the air and used for detecting the temperature of the water in the high-level water tank 11. The high-level water tank 11 is further provided with a second liquid level meter 20, one end of the second liquid level meter 20 is connected to the top of the high-level water tank 11 through a seamless pipeline, and the other end of the second liquid level meter is connected to the bottom of the high-level water tank 11 through a seamless pipeline and used for detecting water level change in the high-level water tank 11. The high-level water tank 11 is also provided with an LED lamp for low-level alarm of the high-level water tank 11. A seventh seamless pipeline 23 is arranged on the high-level water tank 11, one end of the seventh seamless pipeline 23 is connected with the top of the high-level water tank 11, and the other end of the seventh seamless pipeline is connected with a drainage pipeline, so that high-level automatic overflow of the high-level water tank 11 is realized; a sixth seamless pipeline 22 is arranged on the high-level water tank 11, one end of the sixth seamless pipeline 22 is connected with the bottom of the high-level water tank 11, and the other end of the sixth seamless pipeline is connected with a drainage pipeline, so that high-level pollution discharge of the high-level water tank 11 is realized; furthermore, the top of the high-level water tank 11 is connected with a tap water pipe through a fifth seamless pipe 13, when the water amount of the high-level water tank 11 is low, water can be supplemented through the tap water pipe, and the water amount in the high-level water tank 11 is ensured. The fifth seamless pipeline 13 is provided with a ninth flange ball valve 41, the ninth flange ball valve 41 is a manual valve, and water can be supplemented to the head tank 11 by opening the ninth flange ball valve 41. Wherein, the second liquid level meter 20 is a magnetic turning plate liquid level meter with a remote transmission function LI 2101.

Furthermore, the top of the high-level water tank 11 is connected with a steam pipeline of the steam system through a fourth seamless pipeline 12, a third flange stop valve 16, a second flange stop valve 15 and a first flange stop valve 14 are sequentially arranged at a water inlet of the fourth seamless pipeline 12, wherein the second flange stop valve 15 is an electric valve, the second flange stop valve 15 is electrically connected with a free end of a thermal resistor 18, and the high-level water tank 11 is guaranteed to be heated to 100 ℃. When the thermal resistor 18 detects that the water temperature in the high-level water tank 11 is lower than 100 ℃, the control unit controls the second flange stop valve 15 to be opened, a worker manually opens the first flange stop valve 14 and the third flange stop valve 16, the heating system heats the hot water in the high-level water tank 11 to 100 ℃ through the steam pipeline and the fourth seamless pipeline 12, and when the thermal resistor 18 detects that the water temperature in the high-level water tank 11 reaches 100 ℃, the control unit controls the second flange stop valve 15 to be closed. Further, in the case where the second flange stop valve 15 is damaged, the first flange stop valve 14 and the third stop valve are closed, and the second flange stop valve 15 can be easily replaced.

Further, the electrical connection relationship in the present invention is shown in fig. 3 to fig. 7:

the Siemens CPU224XP of the control unit is powered by 24V direct-current voltage, a first output port Q0.0 of the Siemens CPU224XP of the control unit is connected with one end of a coil of a first relay KA1, and the other end of the coil of the first relay KA1 is connected with a power supply 1M; one end of a contact of the first relay KA1 is connected with a power supply input end, the other end of the contact is connected with one end of a hot water pump 9, and the other end of the hot water pump 9 is connected with a power supply common end; a second output port Q0.1 of the Siemens CPU224XP of the control unit is connected with one end of a coil of a second relay KA2, and the other end of the coil of the second relay KA2 is connected with a power supply 1M; contact one end and the power input end of second relay KA2 are connected, and the other end is connected with second flange stop valve 15 one end, and the second flange stop valve 15 other end is connected with the power common. Further, the first electric ball valve 30, the second electric ball valve 36, the standby valve and the control unit siemens CPU224XP are all connected through relays, and are not described herein again. Furthermore, the thermal resistor inputs the water temperature information to the control unit siemens CPU224XP through the expansion interface, and similarly, the water level information detected by the liquid level meter and the flow rate information of the hot water detected by the flow meter are all input to the control unit siemens CPU224XP through the expansion interface.

Further, this implement novel ration adds water installation's concrete theory of operation as follows:

the utility model relates to a ration adds water installation power-on and begins work, the water level variation in the first level gauge 8 real-time detection collecting box 7 feeds back this water level variation information FV1101 to the control unit, when the water in the collecting box 7 is in the low water level, the control unit sends control command FTC1101 and controls hot-water pump 9 and close, when the water in the collecting box 7 is in the high water level, the control unit sends control command FTC1101 and controls hot-water pump 9 and opens, carry the water in the collecting box 7 to high water tank 11. The thermal resistor 18 detects water temperature information in the high-level water tank in real time and feeds the water temperature information TIC2102 back to the control unit, when the thermal resistor 18 detects that the water temperature in the high-level water tank 11 is lower than 100 ℃, the control unit sends a control instruction TV2102 to control the second flange stop valve 15 to be opened, a worker manually opens the first flange stop valve 14 and the third flange stop valve 16, the heating system heats hot water in the high-level water tank 11 to 100 ℃ through the steam pipeline and the fourth seamless pipeline 12, and when the thermal resistor 18 detects that the water temperature in the high-level water tank 11 reaches 100 ℃, the control unit sends a control instruction TV2102 to control the second flange stop valve 15 to be closed. Further, the second liquid level meter 20 detects the water level in the high level tank 11 in real time and feeds back the water level information FV2101 to the control unit, when the second liquid level meter 20 detects that the high level tank 11 is at a low water level, the control unit sends a control instruction FTC2101 to control the acousto-optic alarm lamp to give an alarm, and a worker can manually open the ninth flanged ball valve 41 to replenish water for the high level tank 11. Further, if 300L of water needs to be added in the subsequent white spirit brewing process, in this embodiment, taking the case of adding water by the first water adding gun 39 as an example, specifically, the worker opens the fifth flange ball valve 28, the control unit sends a control command TV3101 to open the first electric ball valve 30, hot water in the high-level water tank 11 is output to the first water adding gun 39 through the eighth seamless pipe 25 and the second water outlet pipe, meanwhile, the first flow meter 29 detects the hot water flow in the second water outlet pipe and feeds back the hot water flow information QIC3101 to the control unit, when the first flow meter 29 detects that the hot water output by the second water outlet pipe reaches 300L, the control unit sends a control command TV3101 to close the first electric ball valve 30, and the water adding work is completed.

The above detailed description is the detailed description of the present invention, and it can not be considered that the detailed description of the present invention is limited to these descriptions, and to the ordinary skilled person in the art to which the present invention belongs, without departing from the concept of the present invention, a plurality of simple deductions and replacements can be made, which should be regarded as belonging to the protection scope of the present invention.

Claims

1. The utility model provides a quantitative water adding device which characterized in that: the device comprises a flow detection unit, a control unit, a water outlet pipeline, a water storage device and a water adding device; the output end of the flow detection unit is connected with the control unit, arranged on the water outlet pipeline and used for detecting the flow of hot water; one end of the water outlet pipeline is connected with the bottom of the water storage device, and the other end of the water outlet pipeline is connected with the water adding device.

2. A quantitative water adding device according to claim 1, characterized in that: the flow detection unit comprises a flow meter, the water storage device comprises a high-level water tank (11), and the water adding device comprises a water adding gun.

3. A quantitative water adding device according to claim 1, characterized in that: the water outlet pipeline comprises a first water outlet pipeline and a second water outlet pipeline, and the first water outlet pipeline is connected with the second water outlet pipeline in an inverted T shape; the first water outlet pipeline comprises an eighth seamless pipeline (25), the second water outlet pipeline comprises a ninth seamless pipeline (42) and a tenth seamless pipeline (43), the water inlet end of the eighth seamless pipeline (25) is connected with the high-level water tank (11) through a fourth flange ball valve (24), and the water outlet end of the eighth seamless pipeline (25) is connected with the water inlet end of the ninth seamless pipeline (42) and the water inlet end of the tenth seamless pipeline (43).

4. A quantitative water adding device according to claim 3, characterized in that: the water inlet end of the ninth seamless pipeline (42) is sequentially provided with a fifth flange ball valve (28), a first flowmeter (29) and a first electric ball valve (30), and the water inlet end of the tenth seamless pipeline (43) is sequentially provided with a seventh flange ball valve (34), a second flowmeter (35) and a second electric ball valve (36).

5. A quantitative water adding device according to claim 2, characterized in that: the device also comprises a collecting box (7), wherein the collecting box (7) is connected with the high-level water tank (11) through a first water inlet pipeline, one end of the first water inlet pipeline is connected to the bottom of the collecting box (7), and the other end of the first water inlet pipeline is connected to the top of the high-level water tank (11).

6. A quantitative water adding device according to claim 5, characterized in that: and a hot water pump (9) is arranged on the first water inlet pipeline and used for conveying hot water in the collecting box (7) to the high-level water tank (11).

7. A quantitative water adding device according to claim 2, characterized in that: the device further comprises an ice bucket, the first ice bucket (1) is connected with the collecting box (7) through a second water inlet pipeline, and the second ice bucket (2) is connected with the collecting box (7) through a third water inlet pipeline.

8. A quantitative water adding device according to claim 2, characterized in that: the device also comprises a water level detection unit, wherein the output end of the water level detection unit is connected with the control unit, arranged on the collection box (7) and the high-level water tank (11) and used for detecting the water levels of the collection box (7) and the high-level water tank (11).

9. A quantitative water adding device according to claim 2, characterized in that: the device also comprises a temperature detection unit, wherein the output end of the temperature detection unit is connected with the control unit, is arranged inside the high-level water tank (11) and is used for detecting the temperature of water in the high-level water tank (11).

10. A quantitative water adding device according to claim 2, characterized in that: the device also comprises an alarm unit which is arranged outside the high-level water tank (11), and the alarm unit is connected with the output end of the control unit and used for receiving the control instruction of the control unit and executing corresponding alarm action.