CN214156119U - Brine flow distribution system - Google Patents

Abstract

A brine flow distribution system relates to the technical field of flow distribution systems and is provided with a pressurizing device, a suction pipe, a flow distribution pipe, a suction valve and a flow distribution valve, wherein the suction pipe and the flow distribution pipe are respectively communicated with the pressurizing device; the arrangement of the distribution valve can separate the brine dispensing nozzle and the pressurizing device through the distribution valve, so that the pressure generated by brine is prevented from directly impacting on the pressurizing device, and a quick-wear part in the pressurizing device is prevented from being prematurely damaged due to overlarge impact force; the arrangement of the flow absorption valve ensures that the brine flowing from the brine tank to the pressurizing device can be isolated when the pressurizing device pressurizes and pumps the brine, and the brine pressurized by the pressurizing device is prevented from directly flowing back to the brine tank, so that the pressure of the tank body of the brine tank is prevented from rising due to the backflow of the brine, and the brine tank is prevented from cracking and damaging due to overhigh pressure of the tank body; in addition, constant brine pressure can be provided, and the brine pressure is prevented from being suddenly high and suddenly low.

Description

Brine flow distribution system

Technical Field

The utility model relates to a join in marriage a class system field, especially relate to a bittern system of joining in marriage.

Background

In the production process of the betel nuts, brine plays a crucial role, can soften the betel nuts and enable the taste of the betel nuts to be better and appropriate, generally speaking, brine is brine-spotted on the betel nuts through a brine-spotting device, specifically, manufacturers can use a pressurizing device to pressurize and pump the brine, so that the brine can be conveyed to a brine-spotting spray head. However, at present, the following technical problems are encountered when marinating the betel nuts:

firstly, when the brine dispensing nozzle dispenses brine, brine is pressurized for the second time, so that the brine can overcome the pressure of a one-way valve on the brine dispensing nozzle and is sprayed to areca nuts, but when the brine dispensing nozzle pressurizes the brine, the brine pressure between the pressurizing device and the brine dispensing nozzle is increased, so that the working pressure of the pressurizing device is increased, and in the brine dispensing process, the brine dispensing nozzle continuously works in a slightly spaced mode to respectively spray brine to each areca nut, so that the continuous work of the brine dispensing nozzle can cause the brine pressure to be high or low, so that the pressurizing device is continuously impacted, and especially when the brine dispensing frequency is high, the impact frequency of the brine to the pressurizing device is also high, and further blades, pistons, sealing rings and the like in the pressurizing device are damaged;

secondly, when pressure device with brine pressure pump send to the point brine shower nozzle on, because pressure device also is with brine case intercommunication simultaneously, consequently, when pressure device pump sending brine, brine probably flows back to in the brine case from pressure device to lead to brine case pressure to rise, and when the box pressure of brine case was too high, still can lead to brine case fracture damage.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, providing a brine flow distribution system, this brine flow distribution system not only can prevent that the brine pressure that the point brine shower nozzle produced from directly impacting to the pressure device in, can also prevent that the brine tank from because of the too high fracture damage of box pressure.

The purpose of the utility model is realized through the following technical scheme:

a brine flow distribution system comprises a pressurizing device, wherein a flow distribution port is formed in the pressurizing device, the brine flow distribution system further comprises a flow suction pipe, a flow distribution pipe, a flow suction valve and a flow distribution valve, the flow suction pipe is respectively communicated with a brine tank and the flow distribution port, and the flow distribution pipe is respectively communicated with a brine dispensing nozzle and the flow distribution port;

wherein the suction valve is used for separating the brine tank and the flow distribution port under the control of the outside; the distribution valve is used for being controlled by the outside to separate the brine dispensing nozzle and the distribution port.

In one embodiment, the brine flow distribution system further comprises a flow distribution joint, the flow distribution joint is communicated with the flow distribution port, and the flow suction pipe and the flow distribution pipe are respectively communicated with the flow distribution joint.

In one embodiment, the distribution valve is a pneumatic control valve.

In one embodiment, the suction valve is a hydraulic control valve.

In one embodiment, the brine flow distribution system further comprises a flow distribution device, wherein the flow distribution device comprises a plurality of flow distribution quick connectors, and each flow distribution quick connector is respectively communicated with the flow distribution pipe.

In one embodiment, the flow dividing device further includes a pressure relief pipe and a pressure relief valve, the pressure relief pipe is communicated with the flow distribution pipe, and the pressure relief valve is disposed on the pressure relief pipe.

In one embodiment, the brine flow distribution system further comprises a flow inlet device, the flow inlet device comprises a flow inlet pipe, a flow inlet valve, a flow inlet pressure relief pipe and a flow inlet pressure relief valve, one end of the flow inlet pipe is communicated with the flow suction pipe, the other end of the flow inlet pipe is communicated with the brine tank, the flow inlet valve is arranged on the flow inlet pipe, the flow inlet pressure relief pipe is communicated with the flow suction pipe, and the flow inlet pressure relief valve is arranged on the flow inlet pressure relief pipe.

In one embodiment, the pressurizing device is further provided with a suction-flow avoiding hole and a distribution-flow avoiding hole, the suction pipe is arranged in the suction-flow avoiding hole in a penetrating manner, and the distribution pipe is arranged in the distribution-flow avoiding hole in a penetrating manner.

In one embodiment, the pressurizing device includes a conveying cylinder, a piston and a driving member, the flow distribution port is located on the conveying cylinder, a pumping channel is further formed in the conveying cylinder, the pumping channel is communicated with the flow distribution port, the piston is located in the pumping channel, the driving member is used for driving the piston to slide along the extending direction of the pumping channel, and the flow suction and avoiding hole and the flow distribution and avoiding hole are both located on the conveying cylinder.

In one embodiment, the conveying cylinder is further provided with a locking hole.

Compared with the prior art, the utility model discloses advantage and beneficial effect below having at least:

the utility model relates to a brine flow distribution system, which relates to the technical field of flow distribution systems and is provided with a pressurizing device, a suction pipe, a flow distribution pipe, a suction valve and a flow distribution valve, wherein the suction pipe and the flow distribution pipe are respectively communicated with the pressurizing device; the arrangement of the distribution valve can separate the brine dispensing nozzle and the pressurizing device through the distribution valve, so that the pressure generated by brine is prevented from directly impacting on the pressurizing device, and a quick-wear part in the pressurizing device is prevented from being prematurely damaged due to overlarge impact force; the arrangement of the flow absorption valve ensures that the brine flowing from the brine tank to the pressurizing device can be isolated when the pressurizing device pressurizes and pumps the brine, and the brine pressurized by the pressurizing device is prevented from directly flowing back to the brine tank, so that the pressure of the tank body of the brine tank is prevented from rising due to the backflow of the brine, and the brine tank is prevented from cracking and damaging due to overhigh pressure of the tank body; in addition, constant brine pressure can be provided, and the brine pressure is prevented from being suddenly high and suddenly low.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a brine flow distribution system according to an embodiment of the present invention;

fig. 2 is a schematic view of an internal structure of a brine flow distribution system according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of another angle of the brine flow distribution system according to an embodiment of the present invention.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, 2 and 3, the brine flow distribution system 10 includes a pressure device 100, a flow distribution port 111 is formed on the pressure device 100, the brine flow distribution system 10 further includes a suction pipe 200, a flow distribution pipe 300, a suction valve 400 and a flow distribution valve 500, the suction pipe 200 is respectively communicated with the brine tank and the flow distribution port 111, and the flow distribution pipe 300 is respectively communicated with the brine dispensing nozzle and the flow distribution port 111.

In the practical application process, the flow suction valve 400 is used for isolating the brine tank and the flow distribution port 111 under the control of the outside; the distributing valve 500 is used for isolating the point halogen spray head and the distributing port 111 under the control of the outside.

It should be noted that the brine flow distribution system 10 is used for extracting brine in the brine tank and also used for pumping the brine to the brine pointing spray head at regular time; the pressurizing device 100 is used for pumping and pumping brine; the flow suction pipe 200 is used for guiding brine in the brine tank to the pressurizing device 100 through the flow distribution port 111; the flow distribution pipe 300 is used for guiding the brine in the pressurizing device 100 to the brine-dispensing nozzle through the flow distribution port 111; the suction valve 400 plays a role of blocking the suction pipe 200; the distributing valve 500 functions to block the distributing pipe 300.

It should be known that, part of the brine-dispensing nozzles realize pressurized injection of brine through the relative movement of the valve core and the valve sleeve, and if the lubrication of brine is lacked between the valve core and the valve sleeve, the abrasion of the valve core and the valve sleeve is accelerated; by adopting the technical scheme of the utility model, in the process of extracting brine by the brine flow distribution system 10, the flow distribution valve 500 blocks the flow distribution pipe 300, so that brine can not flow to the brine dispensing nozzle through the flow distribution pipe 300, and brine can only be pumped into the pressurizing device 100 from the brine tank; therefore, the brine amount at the brine dripping spray head can be ensured, and the vacuum phenomenon in the brine dripping spray head is avoided, so that the quick-wear parts such as an injection valve core at the brine dripping spray head are prevented from being worn out at an accelerated speed due to the lack of brine, and the durability of the brine dripping spray head is further ensured;

furthermore, in the process that the brine distribution system 10 pumps the brine to the brine dispensing nozzle, the suction valve 400 blocks the suction pipe 200, so that the brine pumped by the pressurizing device 100 through the distribution port 111 cannot flow back to the brine tank, and the brine tank is prevented from cracking and being damaged due to overhigh pressure of the tank body;

especially, when adding pressure to brine and spraying at some steamed shower nozzle, according to the pascal principle, brine can transmit pressure to each position department, and the utility model provides a distribution valve 500 then can block brine between some steamed shower nozzle and pressure device 100 for pressure on the some steamed shower nozzle can't transmit to pressure device on, thereby prevents sealing washer or vulnerable part etc. among the pressure device 100 because of the high frequency impact of brine and wearing and tearing with higher speed, has guaranteed pressure device 100's durability.

Referring to fig. 1 and 3, in one embodiment, the brine flow distribution system 10 further includes a flow splitting joint 600, the flow splitting joint 600 is communicated with the flow distribution port 111, and the suction pipe 200 and the flow distribution pipe 300 are respectively communicated with the flow splitting joint 600.

The flow dividing joint 600 functions to communicate the flow distribution port 111 with the suction pipe 200 and the flow distribution pipe 300, respectively.

Referring to fig. 1 and 3 together, in one embodiment, the distributing valve 500 is a pneumatic control valve.

It should be noted that a pneumatic control valve may be used as the distribution valve 500 to control the penetration or the blocking of the distribution pipe 300, so that the penetration or the blocking of the distribution pipe 300 can be controlled only by controlling the direction of the compressed air input into the pneumatic control valve through an external device.

Referring to fig. 1 and 3, in one embodiment, the suction valve 400 is a hydraulic control valve.

It should be noted that the penetration or interruption of the suction pipe 200 may be controlled by using a hydraulic control valve as the suction valve 400, and thus, the penetration or interruption of the suction pipe 200 may be controlled only by controlling the direction of the hydraulic fluid input to the hydraulic control valve by an external device.

In addition to the above, both the distributing valve 500 and the suction valve 400 may be set as pneumatic control valves; the distribution valve 500 and the suction valve 400 may be provided as hydraulic control valves; it is also possible to provide the distribution valve 500 as a pneumatic control valve and the suction valve 400 as a hydraulic control valve; it is also possible to provide the distribution valve 500 as a hydraulic control valve and the suction valve 400 as a pneumatic control valve.

Referring to fig. 1 and fig. 3, in one embodiment, the brine flow distribution system 10 further includes a flow distribution device 700, the flow distribution device 700 includes a plurality of flow distribution quick connectors 710, and each flow distribution quick connector 710 is respectively communicated with the flow distribution pipe 300.

It should be noted that the flow dividing device 700 is used for dividing brine; the setting of reposition of redundant personnel quick-operation joint 710 for the workman can use fast with some bittern shower nozzle and join in marriage a class pipe 300 intercommunication or separation, has improved the dismouting convenience that bittern joined in marriage a class system.

When the bittern dispensing nozzle or the flow distribution pipe 300 needs to be disassembled for maintenance, certain pressure often exists in the bittern in the flow injection pipe 330, and the disassembly and separation of the bittern dispensing nozzle and the flow distribution pipe 300 can cause high-pressure splashing of the bittern, so that the danger coefficient is very large;

to address the technical problem, please refer to fig. 1 and fig. 3, the flow dividing device 700 further includes a pressure relief pipe 720 and a pressure relief valve 730, the pressure relief pipe 720 is communicated with the flow distributing pipe 300, and the pressure relief valve 730 is disposed on the pressure relief pipe 720.

It should be noted that, the maintainer only needs to open the relief valve 730, and brine can flow out from the flow distribution pipe 300 along the relief pipe 720, so that the pressure in the pipe of the flow distribution pipe 300 can be reduced to be consistent with atmospheric pressure, thereby avoiding risks such as sputtering when detaching the brine sprayer or the flow distribution pipe 300.

Referring to fig. 1, the brine flow distribution system 10 further includes a flow inlet device 800, the flow inlet device 800 includes a flow inlet tube 810, a flow inlet valve 820, a flow inlet pressure relief tube 830 and a flow inlet pressure relief valve 840, one end of the flow inlet tube 810 is communicated with the flow suction tube 200, the other end of the flow inlet tube 810 is communicated with the brine tank, the flow inlet valve 820 is disposed on the flow inlet tube 810, the flow inlet pressure relief tube 830 is communicated with the flow suction tube 200, and the flow inlet pressure relief valve 840 is disposed on the flow inlet pressure relief tube 830.

It should be noted that the inflow device 800 is used for guiding the brine in the brine tank to the flow suction pipe 200; the arrangement of the inlet valve 820 enables an operator to manually separate the brine tank from the suction pipe 200 when needed; in addition, the maintainer only needs to open the inflow relief valve 840 to reduce the pressure in the inflow tube 810, the brine tank and the flow suction tube 200 to the atmospheric pressure value, so that the situation of brine sputtering when the inflow tube 810, the brine tank and the flow suction tube 200 are maintained is avoided.

Referring to fig. 1 and fig. 2, in one embodiment, the pressurizing device 100 further has a suction-flow avoiding hole 112 and a distribution-flow avoiding hole 113, the suction tube 200 is inserted into the suction-flow avoiding hole 112, and the distribution tube 300 is inserted into the distribution-flow avoiding hole 113.

It should be noted that the suction flow avoiding hole 112 is used for accommodating the suction pipe 200, so that the suction pipe 200 can communicate with the flow distribution port 111; the flow distribution avoiding hole 113 is formed so that the flow distribution pipe 300 can communicate with the flow distribution port 111.

Further, referring to fig. 1 and fig. 2, in one embodiment, the pressurizing device 100 includes a conveying cylinder 110, a piston 120, and a driving member 130, the flow distribution port 111 is located on the conveying cylinder 110, the conveying cylinder 110 is further provided with a pumping channel 114, the pumping channel 114 is communicated with the flow distribution port 111, the piston 120 is located in the pumping channel 114, the driving member 130 is used for driving the piston 120 to slide along the extending direction of the pumping channel 114, and the suction flow avoiding hole 112 and the flow distribution avoiding hole 113 are both located on the conveying cylinder 110.

The conveying cylinder 110 is used for accommodating brine; in practice, the driving member 130 will increase or decrease the pressure in the pumping channel 114 by driving the piston 120 to slide in the pumping channel 114, so as to achieve the purpose of pumping or pumping brine.

Specifically, the driving member 130 may be a cylinder or a cylinder.

Referring to fig. 3, in one embodiment, the conveying cylinder 110 further has a locking hole 115.

It should be noted that the locking hole 115 is formed, so that a worker can fix the pressure device 100 by only passing a screw through the locking hole 115 and screwing the screw to a predetermined position.

Compared with the prior art, the utility model discloses advantage and beneficial effect below having at least:

the utility model relates to a brine flow distribution system, which relates to the technical field of flow distribution systems and is provided with a pressurizing device, a suction pipe, a flow distribution pipe, a suction valve and a flow distribution valve, wherein the suction pipe and the flow distribution pipe are respectively communicated with the pressurizing device; the arrangement of the distribution valve can separate the brine dispensing nozzle and the pressurizing device through the distribution valve, so that the pressure generated by brine is prevented from directly impacting on the pressurizing device, and a quick-wear part in the pressurizing device is prevented from being prematurely damaged due to overlarge impact force; the arrangement of the flow absorption valve ensures that the brine flowing from the brine tank to the pressurizing device can be isolated when the pressurizing device pressurizes and pumps the brine, and the brine pressurized by the pressurizing device is prevented from directly flowing back to the brine tank, so that the pressure of the tank body of the brine tank is prevented from rising due to the backflow of the brine, and the brine tank is prevented from cracking and damaging due to overhigh pressure of the tank body; in addition, constant brine pressure can be provided, and the brine pressure is prevented from being suddenly high and suddenly low.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A brine flow distribution system comprises a pressurizing device, wherein a flow distribution port is formed in the pressurizing device, and the brine flow distribution system is characterized by further comprising a flow suction pipe, a flow distribution pipe, a flow suction valve and a flow distribution valve, wherein the flow suction pipe is respectively communicated with a brine tank and the flow distribution port, and the flow distribution pipe is respectively communicated with a brine dispensing nozzle and the flow distribution port;

wherein the suction valve is used for separating the brine tank and the flow distribution port under the control of the outside; the distribution valve is used for being controlled by the outside to separate the brine dispensing nozzle and the distribution port.

2. The brine flow distribution system of claim 1, further comprising a flow distribution joint in communication with the flow distribution port, wherein the flow suction pipe and the flow distribution pipe are in communication with the flow distribution joint, respectively.

3. The brine flow distribution system of claim 1 or 2, wherein the flow distribution valve is a pneumatic control valve.

4. The brine flow distribution system of claim 1, wherein the suction valve is a hydraulic control valve.

5. The brine flow distribution system of claim 1, further comprising a flow distribution device comprising a plurality of flow distribution quick connectors, each quick connector being in communication with the flow distribution pipe.

6. The brine flow distribution system of claim 5, wherein the flow splitting device further comprises a pressure relief pipe and a pressure relief valve, the pressure relief pipe is communicated with the flow distribution pipe, and the pressure relief valve is disposed on the pressure relief pipe.

7. The brine flow distribution system of claim 1, further comprising a flow inlet device, wherein the flow inlet device comprises a flow inlet pipe, a flow inlet valve, a flow inlet pressure relief pipe and a flow inlet pressure relief valve, one end of the flow inlet pipe is communicated with the flow suction pipe, the other end of the flow inlet pipe is communicated with the brine tank, the flow inlet valve is disposed on the flow inlet pipe, the flow inlet pressure relief pipe is communicated with the flow suction pipe, and the flow inlet pressure relief valve is disposed on the flow inlet pressure relief pipe.

8. The brine flow distribution system of claim 1, wherein the pressurizing device further comprises a suction hole and a distribution hole, the suction pipe is disposed through the suction hole, and the distribution pipe is disposed through the distribution hole.

9. The brine flow distribution system of claim 8, wherein the pressurizing device comprises a conveying cylinder, a piston and a driving member, the flow distribution port is located on the conveying cylinder, the conveying cylinder is further provided with a pumping channel, the pumping channel is communicated with the flow distribution port, the piston is located in the pumping channel, the driving member is used for driving the piston to slide along the extending direction of the pumping channel, and the flow suction and avoiding hole and the flow distribution and avoiding hole are both located on the conveying cylinder.

10. The brine flow distribution system of claim 9, wherein the transport cylinder is further provided with locking holes.

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