CN209952352U

CN209952352U - Separating tank

Info

Publication number: CN209952352U
Application number: CN201920592116.7U
Authority: CN
Inventors: 徐峻峰; 徐霄
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-04-26
Filing date: 2019-04-26
Publication date: 2020-01-17
Anticipated expiration: 2029-04-26

Abstract

The application discloses a separating tank, which comprises a tank body, wherein the tank body is provided with a first water outlet, a first water inlet, a second water outlet and a second water inlet, a T-shaped decoupling pipe is arranged in the tank body, the two ends of the upper side of the T-shaped decoupling pipe are respectively connected with the first water inlet and the second water outlet, the lower side of the T-shaped decoupling pipe is provided with a decoupling hole, the separating tank is arranged between a primary pump at the host side of an air-conditioning water system and a secondary pump at the user side, so that the fluids at the host side and the user side do not influence each other any more, the water path separation at the host side and the user side is realized, the flow, the resistance and the power consumption of the system are reduced, the separating tank completely separates the gas (steam) bodies at the user side and the host side, and concentrates the gas (steam) bodies at the same time, thereby avoiding the influence of the gas on the primary pump at the host side and the secondary pump at the user, thereby greatly reducing the failure rate.

Description

Separating tank

Technical Field

The utility model relates to an air conditioner water system technical field, concretely relates to knockout drum.

Background

In the existing air-conditioning water system, a primary pump at a host side and a secondary pump at a user side can interfere with each other when working simultaneously, the secondary pump at the user side is connected with a multi-way circulating pipeline, so that the pressure difference at the host side is easy to change violently, the energy consumption of the system is high, the system is easy to damage, and air is difficult to avoid in the air-conditioning water system.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above problem, a knockout drum is proposed.

The utility model adopts the following technical scheme:

the utility model provides a separating tank, includes a jar body, first delivery port, first water inlet, second delivery port and second water inlet have on the jar body, the internal T type pipe of decoupling that is equipped with of jar, T type pipe of decoupling's T word upside both ends are connected respectively first water inlet with the second delivery port, T type pipe of decoupling's T word downside is equipped with the hole of decoupling.

The water tank is characterized in that an impurity separation device is arranged in the tank body and is positioned at the second water inlet so as to separate impurities from the water entering the tank body through the second water inlet.

The impurity separation device comprises a separation box, the separation box cover is arranged on the second water inlet, the separation box comprises a front separation plate and a lower separation plate, the front separation plate is located at the front end of the second water inlet, the lower separation plate is located at the lower side of the second water inlet, and a filter hole is formed in the front separation plate and the lower separation plate.

Further, the front separation plate and the lower separation plate are provided with baffle pipes extending out of the filter holes.

Further, the free end of the baffle pipe is arranged towards the direction of the second water inlet.

The separating box is characterized in that a drain outlet is arranged on the tank body and is arranged at the lower side of the second water inlet, the drain outlet is communicated with the lower part of the separating box, and the drain outlet is connected with the first drain valve through a pipeline.

The first water outlet and the first water inlet are positioned on the same side, and the second water outlet and the second water inlet are positioned on the same side.

The tank body is further provided with an observation hole, and the observation hole is positioned above the first water outlet.

Further, an exhaust valve is arranged at the top end of the tank body.

Further, a second blow-down valve is arranged at the bottom end of the tank body.

The utility model has the advantages that: the separation tank of the utility model is arranged between the primary pump at the host side and the secondary pump at the user side of the air-conditioning water system, the fluid at the host side and the fluid at the user side can not influence each other, the water path separation at the host side and the user side is realized, the flow of the primary pump is controlled to be more than or equal to the flow of the secondary pump, because the T-shaped decoupling pipe is arranged between the first water inlet and the second water outlet, and because the lower side of the T shape of the T-shaped decoupling pipe is provided with the decoupling hole, the redundant water flows out from the decoupling hole, the temperatures at the first water inlet and the second water outlet are approximately equal, the flow, the resistance and the power consumption of the system are reduced, and the separating tank of the utility model completely separates the gas (steam) at the user side and the main machine side, meanwhile, gas (steam) is concentrated, so that the influence of the gas on the primary pump at the host side and the secondary pump at the user side is avoided, and the fault rate is greatly reduced.

Drawings

FIG. 1 is a schematic structural view of a separation tank of the present invention;

FIG. 2 is a schematic view of the connection of the separation tank with the primary pump and the secondary pump;

fig. 3 is a schematic structural view of the impurity separating device.

The figures are numbered: 1. a tank body; 11. a first water outlet; 12. a first water inlet; 13. a second water outlet; 14. a second water inlet; 15. a sewage draining outlet; 16. a temperature sensor; 2. a T-shaped decoupling tube; 21. a decoupling aperture; 3. an impurity separation device; 31. a separation box; 32. a front separator plate; 33. a lower separator plate; 34. a filtration pore; 35. blocking the pipe; 4. a primary pump; 5. a secondary pump; 6. a first waste valve; 7. a second blowoff valve; 8. an observation hole; 9. and (4) exhausting the valve.

Detailed Description

The above and further features and advantages of the present invention will be apparent from the following, more complete description of the invention, taken in conjunction with the accompanying drawings, in which it is to be understood that the described embodiments are merely some, and not all, of the embodiments of the invention.

Referring to fig. 1-3, the utility model provides a separating tank, which comprises a tank body 1, first delivery port 11 has on the jar body 1, first water inlet 12, second delivery port 13 and second water inlet 14, first delivery port 11 is used for connecting the inlet tube of the primary pump 4 of host computer side, first water inlet 12 is used for connecting the outlet pipe of the primary pump 4 of host computer side, second delivery port 13 is used for connecting the inlet tube of the secondary pump 5 of user side, second water inlet 14 is used for connecting the outlet pipe of the secondary pump 5 of user side, be equipped with T type decoupling pipe 2 in jar body 1, first water inlet 12 and second delivery port 13 are connected respectively to T type decoupling pipe 2's T word upside both ends, T type decoupling pipe 2's T word downside is equipped with decoupling hole 21.

Set up between the secondary pump 5 of the primary pump 4 of the host side of air conditioner water system and user side the utility model discloses the knockout drum, the water that gets into the primary pump 4 of host side is flowed by the first delivery port 11 of the jar body 1, and the water in the primary pump 4 flows into the T type decoupling pipe 2 of the jar body 1 from first water inlet 12 in, flows to the secondary pump 5 of user side by second delivery port 13 again, and the water in the secondary pump 5 flows to the jar body 1 from second water inlet 14. Because the T-shaped decoupling pipe 2 is provided with the decoupling hole 21, the decoupling hole 21 is communicated with the tank body 1, when more water flows out of the primary pump 4, the redundant water can flow out of the decoupling hole 21 and enter the tank body 1, and the excessive water can not flow to the secondary pump 5 from the T-shaped decoupling pipe 2, so that the water flowing in and out of the primary pump 4 at the host side and the secondary pump 5 at the user side can not influence each other, the water path separation of the host side and the user side is realized, the flow of the primary pump 4 is controlled to be more than or equal to the flow of the secondary pump 5, the T-shaped decoupling pipe 2 is arranged between the first water inlet 12 and the second water outlet 13, and the decoupling hole 21 is arranged at the lower side of the T shape of the T-shaped decoupling pipe 2, and the redundant water flows out of the decoupling hole 21, so that the temperatures at the first water inlet 12 and the second water outlet 13 are approximately equal, and the flow.

When gas (steam) is present in the user-side pipe, the gas (steam) flows into the tank body 1 from the second water inlet 14 with the water flow without being entangled to the host side, and similarly, when gas (steam) is present in the host-side pipe, the gas (steam) escapes into the tank body 1 from the decoupling hole 21 with the water flow through the T-shaped decoupling pipe 2 without being entangled to the user side. The tank body 1 concentrates gas (steam), so that the influence of the gas on the primary pump 4 at the host side and the secondary pump 5 at the user side is avoided, and the fault rate is greatly reduced.

During cooling, the water flowing out of the decoupling bore 21 can pre-cool the superheated water flowing back from the second water inlet 14, and thus cushion the thermal shock to the main machine.

Referring to fig. 1, temperature sensors 16 are provided at the first water outlet 11 and the first water inlet 12 to monitor the temperature of the water entering the primary pump 4 from the tank 1 and the water entering the tank 1 from the primary pump 4.

Referring to fig. 1, the difference from the above embodiment is that an impurity separation device 3 is disposed in the tank body 1, and the impurity separation device 3 is located at the second water inlet 14 to separate impurities from water entering the tank body 1 through the second water inlet 14, and the water flushed into the tank body 1 from the second water inlet 14 is separated from impurities through the impurity separation device 3, so that the impurities in the water are prevented from entering the primary pump 4 and the secondary pump 5 again, the operation of the primary pump 4 and the secondary pump 5 is affected, the primary pump 4 and the secondary pump 5 are protected, and the failure rate of the system is reduced.

Referring to fig. 1 and 3, the impurity separator 3 includes a separation box 31, the separation box 31 covers the second water inlet 14, the separation box 31 includes a front separation plate 32 and a lower separation plate 33, the front separation plate 32 is located at the front end of the second water inlet 14, the lower separation plate 33 is located at the lower side of the second water inlet 14, and the front separation plate 32 and the lower separation plate 33 are provided with filter holes 34. The water from the second water inlet 14 rushes into the tank body 1 to the front separation plate 32 and the lower separation plate 33, the water flows through the filtering holes 34 on the front separation plate 32 and the lower separation plate 33, and the impurities are filtered.

Referring to fig. 3, the difference from the above embodiment is that the front separation plate 32 and the lower separation plate 33 have baffle pipes 35 extending from the filtering holes 34. When the water flow rushes towards the front separation plate 32 and the lower separation plate 33, impurities are separated, and the filter holes 34 extend out of the baffle pipes 35, so that the impurities can be prevented from passing through the filter holes 34 in the downward moving process, and the impurities can be prevented from blocking the filter holes 34. Preferably, the free end of the baffle 35 is disposed toward the second water inlet 14, so that the water flow can pass through the filtering holes 34 more smoothly. Preferably, the water inlet at the free end of the baffle 35 has a mesh hole with a diameter smaller than that of the filtering holes 34, so that the water rushing towards the front separation plate 32 and the lower separation plate 33 is finely filtered to filter out smaller impurities, and the impurity filtering rate can reach more than 99%.

Referring to fig. 1, the difference from the above embodiment is that a sewage draining exit 15 is arranged on the tank body 1, the sewage draining exit 15 is arranged at the lower side of the second water inlet 14, the sewage draining exit 15 is communicated with the lower part of the separation box 31, and the sewage draining exit 15 is connected with the first sewage draining valve 6 through a pipeline. The impurities separated by the front separation plate 32 and the lower separation plate 33 flow to the lower part along the flow passage to be collected, the first blow-down valve 6 is opened, and the impurities are discharged from the blow-down port 15.

Referring to fig. 1, the difference from the above embodiment is that the first water outlet 11 and the first water inlet 12 are located on the same side, and the second water outlet 13 and the second water inlet 14 are located on the same side, so as to reduce the winding of the pipeline.

Referring to fig. 1, the difference from the above embodiment is that the tank 1 is provided with an observation hole 8, and the observation hole 8 is located above the first water outlet 11. Debugging or maintainer accessible observation hole 8 know the water level condition and the steam-water separation condition, make things convenient for maintenance and water level to observe.

Referring to fig. 1, the difference from the above embodiment is that a vent valve 9 is provided at the top end of the can body 1. The gas (steam) in the tank body 1 is orderly discharged out of the tank body 1 and a water system through the exhaust valve 9, so that the steam-water separation is completed.

Referring to fig. 1, the difference from the above embodiment is that a second blow-off valve 7 is provided at the bottom end of the tank 1 to discharge impurities accumulated at the bottom end of the tank 1.

Although the present invention has been disclosed in the preferred embodiments, it is not intended to limit the present invention, and any person skilled in the art can use the above-mentioned method and technical contents to make possible changes and modifications to the technical solution of the present invention without departing from the spirit and scope of the present invention, therefore, any simple modification, equivalent changes and modifications made to the above embodiments by the technical substance of the present invention all belong to the protection scope of the technical solution of the present invention.

Claims

1. The utility model provides a knockout drum, its characterized in that, includes a jar body, first delivery port, first water inlet, second delivery port and second water inlet have on the jar body, jar internal T type decoupling pipe that is equipped with, T type decoupling pipe's T word upside both ends are connected respectively first water inlet with the second delivery port, T type decoupling pipe's T word downside is equipped with the hole of decoupling.

2. The separator tank of claim 1, wherein a contaminant separator is positioned within the tank body and is positioned at the second water inlet to separate contaminants from water entering the tank body from the second water inlet.

3. The separation tank of claim 2, wherein the impurity separating means comprises a separation box, the separation box cover is disposed on the second water inlet, the separation box comprises a front separation plate and a lower separation plate, the front separation plate is disposed at the front end of the second water inlet, the lower separation plate is disposed at the lower side of the second water inlet, and the front separation plate and the lower separation plate are provided with filtering holes.

4. The separator tank of claim 3, wherein said front separator plate and said lower separator plate have baffles extending from said filter aperture.

5. A separator tank according to claim 4, wherein the free end of the baffle is arranged towards the second inlet opening.

6. The separating tank of claim 3, wherein a sewage draining outlet is arranged on the tank body and is arranged at the lower side of the second water inlet, the sewage draining outlet is communicated with the lower part of the separating box, and the sewage draining outlet is connected with the first sewage draining valve through a pipeline.

7. The separator tank of claim 1, wherein said first water outlet and said first water inlet are on the same side, and said second water outlet and said second water inlet are on the same side.

8. The separator tank of claim 1, wherein the tank body is provided with a viewing aperture, the viewing aperture being positioned above the first water outlet.

9. The separator tank of claim 1, wherein the top end of the tank body is provided with a vent valve.

10. The separator tank of claim 1, wherein a second blowdown valve is provided at a bottom end of the tank body.