Energy-saving fluid control solenoid valve
By introducing a detachable fluid handling mechanism and an electromagnetic regulating mechanism into the solenoid valve, the problems of multiple fluid reversals and flow obstruction are solved, achieving efficient and clean fluid transmission and flow regulation, and improving the energy efficiency and service life of the solenoid valve.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHANGHAI JULIANG VALVE GRP CO LTD
- Filing Date
- 2023-05-10
- Publication Date
- 2026-06-19
AI Technical Summary
In existing solenoid valves, the fluid flow within the valve body needs to be reversed multiple times, and the valve body and valve cover can obstruct fluid flow, affecting fluid transmission efficiency.
An energy-saving fluid control solenoid valve is designed, which includes a detachable fluid handling mechanism, including a handling mechanism support, a fluid filter assembly, and a handling assembly. It can filter and purify fluid, and is equipped with an electromagnetic adjustment mechanism to achieve flow regulation and avoid multiple fluid reversals.
It achieves clean filtration and purification of fluids, improves fluid transmission efficiency, avoids damage to the valve body core assembly, and can adapt to different flow requirements, while being energy-saving and environmentally friendly.
Smart Images

Figure CN116538300B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of fluid control technology, and in particular relates to an energy-saving fluid control solenoid valve. Background Technology
[0002] A solenoid valve is an industrial device controlled by electromagnetic induction. Generally, solenoid valves are basic automated components used to control fluids. They are used in industrial control systems to adjust the flow direction, flow rate, flow speed, and other parameters of the medium. Currently, there are many types of commonly used solenoid valves. Different solenoid valves play a role at different positions in the flow of the medium. Commonly used solenoid valves include check valves, safety valves, directional control valves, and speed regulating valves.
[0003] A search revealed a Chinese patent with publication number "CN105972244A" entitled "A Plastic Diaphragm Solenoid Valve." This solenoid valve includes a valve body, a valve cover bolted to the upper end of the valve body, a sealing mechanism between the valve body and the valve cover, and an electromagnetic actuator mounted on the upper end of the valve cover. The valve body is made of plastic, the sealing mechanism between the valve body and the valve cover is a T-shaped diaphragm, and the electromagnetic actuator includes a moving iron core, a pilot head, and an electromagnetic coil. However, in existing solenoid valves, the fluid flow within the valve body requires multiple reversals, and the valve body and valve cover obstruct the fluid flow, thus affecting fluid transmission. Based on this, we propose an energy-saving fluid control solenoid valve. Summary of the Invention
[0004] In existing solenoid valves, the fluid flow within the valve body requires multiple reversals, and the valve body and valve cover obstruct the fluid flow, thus affecting fluid transmission. Therefore, we propose an energy-saving fluid control solenoid valve. The energy-saving fluid control solenoid valve includes a solenoid valve body, within which a fluid processing mechanism is detachably installed. The fluid processing mechanism is used for fluid filtration and purification. The fluid processing mechanism includes a processing mechanism support, a fluid filter assembly, and a fluid processing component that works in conjunction with the fluid filter assembly. The fluid processing component can absorb harmful substances in the fluid, ensuring the cleanliness of the fluid, while the fluid filter assembly can filter impurities in the fluid.
[0005] This invention is achieved by providing an energy-saving fluid control solenoid valve, which includes:
[0006] The solenoid valve body includes an inlet pipe and a drain pipe connected to the inlet pipe. The inlet pipe and the drain pipe are connected through an electromagnetic adjustment mechanism, and a purification chamber is formed at the connection between the inlet pipe and the electromagnetic adjustment mechanism.
[0007] A detachable fluid handling mechanism is installed inside the purification chamber, which is used for fluid filtration and purification.
[0008] The fluid handling mechanism includes:
[0009] The fluid handling mechanism support is detachably installed inside the purification chamber to support the fluid handling mechanism.
[0010] A fluid filtration assembly, mounted on a support of the processing unit, is used for the filtration and purification of fluids.
[0011] The fluid treatment component, mounted on the support of the treatment mechanism, is used to treat harmful substances flowing into the purification chamber and works in conjunction with the fluid filtration component.
[0012] Preferably, the fluid processing mechanism further includes a support adjustment assembly for adjusting the position of the support seat of the processing mechanism, the support adjustment assembly comprising:
[0013] At least one set of support and adjustment grooves is provided inside the support seat of the processing mechanism;
[0014] A support drive unit installed in the support adjustment groove, wherein the support drive unit is provided with at least one set, and
[0015] The support drive unit is connected to the support drive unit, and the other end of the support drive unit is connected to the liquid inlet pipe.
[0016] Preferably, the fluid filtration assembly includes:
[0017] A fluid purification mechanism includes a purification mechanism mounting base, which is detachably mounted on a processing mechanism support base, and a fluid filtration section is provided inside the purification mechanism mounting base for filtering the discharged fluid.
[0018] The purification and anti-clogging mechanism is located on one side of the fluid purification mechanism and installed in the treatment mechanism support to prevent clogging of the fluid purification mechanism.
[0019] Preferably, the purification and anti-clogging mechanism includes:
[0020] An anti-clogging component is located on one side of the fluid purification mechanism to prevent clogging of the fluid purification mechanism;
[0021] An anti-clogging drive assembly is installed in the support of the processing mechanism and connected to the anti-clogging assembly for adjusting the position of the anti-clogging assembly.
[0022] Preferably, the anti-clogging drive component includes:
[0023] The anti-clogging drive unit is fixedly installed inside the processing mechanism support;
[0024] An anti-clogging transmission unit is fixedly connected to the anti-clogging drive unit, and an anti-clogging driven unit that works in conjunction with the anti-clogging transmission unit is provided on one side of the anti-clogging transmission unit.
[0025] An anti-clogging rotating part is fixedly connected to the anti-clogging driven part, and the anti-clogging rotating part is provided on one side of the anti-clogging driven part.
[0026] Preferably, the anti-clogging drive component further includes:
[0027] An active actuating component is installed on the anti-clogging rotating part and is used for the transmission of power between the anti-clogging rotating part and the anti-clogging driving part;
[0028] A driven pusher is connected to the active pusher, and the driven pusher is fixedly connected to the anti-clogging component for adjusting the position of the anti-clogging component.
[0029] Preferably, the anti-clogging component includes:
[0030] A movable anti-clogging mounting bracket, and multiple sets of anti-clogging limit grooves are installed on the anti-clogging mounting bracket;
[0031] At least one set of anti-clogging components is installed in the anti-clogging limit groove to clean the fluid purification mechanism and prevent it from becoming clogged.
[0032] Preferably, the fluid processing assembly includes:
[0033] At least one set of fluid processing units, said fluid processing units being installed within a processing mechanism support, and said fluid processing units comprising:
[0034] Main processing component;
[0035] An auxiliary processing unit is fixedly connected to the main processing unit, and both the main processing unit and the auxiliary processing unit have multiple sets of fluid processing tanks. These fluid processing tanks are used to purify the fluid, treat harmful substances in the fluid, and...
[0036] The processing unit drive unit is used to adjust the position of the main processing unit and the auxiliary processing unit, and the processing unit fixing unit is fixedly installed in the processing mechanism support.
[0037] Preferably, it further includes a detachable fluid silencing mechanism for collecting impurities in the fluid, the fluid silencing mechanism comprising:
[0038] At least one set of silencer mounting brackets is detachably installed inside the liquid inlet pipe;
[0039] A fluid silencing component installed on a silencing mechanism mounting base; the fluid silencing component is used to silence the flow of fluid.
[0040] Preferably, it further includes an electromagnetic regulating mechanism for adapting to different fluid flow rate requirements, used to change the fluid discharge flow rate, the electromagnetic regulating mechanism comprising:
[0041] A power supply base is fixedly connected to the liquid inlet pipe, and a valve chamber is provided inside the power supply base, which is in continuous communication with the purification chamber;
[0042] An electromagnetic housing disposed on one side of the power supply base;
[0043] A magnetic base is embedded at one end of the electromagnetic housing. A magnetic induction base is fixedly connected to one side of the magnetic base. A magnetic induction coil is wound inside the magnetic induction base. The magnetic induction coil is electrically connected to the power supply base.
[0044] A moving iron core is set in the magnetic induction base. The moving iron core is slidably connected to the electromagnetic housing. A sealing ring for limiting the movement of the moving iron core is provided in the electromagnetic housing. A return spring is fixedly embedded on one side of the moving iron core. A valve body core assembly is detachably connected to the other side of the moving iron core. The valve body core assembly is used to open or close the drain pipe. The valve body core assembly is movably installed in the valve cavity.
[0045] The valve body core assembly includes:
[0046] A valve stem, one end of which is detachably connected to a moving iron core;
[0047] A valve disc mounted at the end of a valve stem, the valve disc being used to open or close the valve chamber.
[0048] Compared with the prior art, the embodiments of this application have the following main advantages:
[0049] This invention discloses a fluid processing mechanism, which includes a processing mechanism support, a fluid filtration assembly, and a fluid processing component that works in conjunction with the fluid filtration assembly. The fluid processing component can process and absorb harmful substances in the fluid, ensuring the cleanliness of the fluid. The fluid filtration assembly can filter impurities in the fluid. At the same time, the filtration process relies on the flow of the fluid and the transmission of driving force, making the process energy-saving and environmentally friendly.
[0050] In this embodiment of the invention, an electromagnetic adjustment mechanism is provided to adapt to different fluid flow requirements. The electromagnetic adjustment mechanism can adjust the fluid flow, and the fluid flow does not need to be reversed multiple times to open or close the drain pipe, thus avoiding damage to the valve body core assembly. When the magnetic coil is de-energized, the restoring force of the reset spring acts on the moving iron core, causing the moving iron core to drive the valve disc in the valve body core assembly to close the valve cavity.
[0051] In this embodiment of the invention, one end of the anti-clogging transmission part extends into the air circulation chamber, realizing the linkage transmission of power to the anti-clogging drive part, thereby achieving energy saving and avoiding clogging of the fluid purification mechanism. Attached Figure Description
[0052] Figure 1 This is a schematic diagram of the structure of an energy-saving fluid control solenoid valve provided by the present invention.
[0053] Figure 2 This is an isometric view of the present invention.
[0054] Figure 3 This is the front view of the present invention.
[0055] Figure 4 This is a rear view of the present invention.
[0056] Figure 5 This is a side view of the present invention.
[0057] Figure 6 This is a schematic diagram of the structure of the solenoid valve body provided by the present invention.
[0058] Figure 7 This is an isometric view of the solenoid valve body provided by the present invention.
[0059] Figure 8 This is a left view of the solenoid valve body provided by the present invention.
[0060] Figure 9 This is a right view of the solenoid valve body provided by the present invention.
[0061] Figure 10 This is a schematic diagram of the electromagnetic adjustment mechanism provided by the present invention.
[0062] Figure 11 This is a front view of the electromagnetic adjustment mechanism provided by the present invention.
[0063] Figure 12 yes Figure 11 A sectional view along the AA direction.
[0064] Figure 13 yes Figure 11 BB-direction sectional view.
[0065] In the diagram: 1-Solenoid valve body, 11-Inlet pipe, 111-Purification chamber, 12-Drain pipe, 13-Main body mounting base, 131-Main body mounting base, 2-Solenoid adjustment mechanism, 21-Solenoid housing, 22-Magnetic induction seat, 221-Magnetic induction coil, 23-Magnetic conductor seat, 24-Reset spring, 25-Sealing ring, 26-Moving iron core, 3-Fluid silencing mechanism, 31-Silencing mechanism mounting base, 32-Fluid silencing component, 4-Valve body core assembly, 41-Valve stem, 42-Valve disc, 43-Valve cavity, 5-Fluid processing mechanism, 51-Processing mechanism support, 52 - Support adjustment tank, 53- Support drive unit, 54- Support transmission unit, 55- Fluid treatment assembly, 551- Processing component drive unit, 552- Main processing component, 553- Fluid treatment tank, 554- Auxiliary processing component, 6- Fluid filtration assembly, 61- Purification mechanism mounting base, 7- Purification anti-clogging mechanism, 71- Anti-clogging drive unit, 72- Anti-clogging transmission unit, 73- Anti-clogging driven unit, 74- Anti-clogging rotating unit, 75- Active pusher, 76- Driven pusher, 77- Anti-clogging assembly, 771- Anti-clogging mounting bracket, 772- Anti-clogging component. Detailed Implementation
[0066] Unless otherwise defined, 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 application belongs; the terminology used herein in the specification of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "comprising" and "having," and any variations thereof, in the specification, claims, and foregoing drawings of this application are intended to cover non-exclusive inclusion. The terms "first," "second," etc., in the specification, claims, or foregoing drawings of this application are used to distinguish different objects, not to describe a particular order.
[0067] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.
[0068] In existing solenoid valves, the fluid flow within the valve body requires multiple reversals, and the valve body and valve cover obstruct the fluid flow, thus affecting fluid transmission. Therefore, we propose an energy-saving fluid control solenoid valve. The energy-saving fluid control solenoid valve includes a solenoid valve body 1, within which a fluid processing mechanism 5 is detachably installed. The fluid processing mechanism 5 is used for fluid filtration and purification. The fluid processing mechanism 5 includes a processing mechanism support 51, a fluid filter assembly 6, and a fluid processing component 55 that works in conjunction with the fluid filter assembly 6. The fluid processing component 55 can process and absorb harmful substances in the fluid, ensuring the cleanliness of the fluid, while the fluid filter assembly 6 can filter impurities in the fluid.
[0069] This invention provides an energy-saving fluid control solenoid valve, such as... Figure 1-5 As shown, the energy-saving fluid control solenoid valve includes:
[0070] The solenoid valve body 1 includes an inlet pipe 11 and a drain pipe 12 connected to the inlet pipe 11. The inlet pipe 11 and the drain pipe 12 are connected through an electromagnetic adjustment mechanism 2, and a purification chamber 111 is formed at the connection between the inlet pipe 11 and the electromagnetic adjustment mechanism 2.
[0071] A detachable fluid processing mechanism 5 is installed inside the purification chamber 111. The fluid processing mechanism 5 is used for fluid filtration and purification.
[0072] In this embodiment, the inlet pipe 11 and the electromagnetic adjustment mechanism 2 are fixedly connected by a clamp, and a sealing flange is provided at the connection to prevent fluid leakage. The inlet pipe 11 adopts a cylindrical structure, while the outlet pipe 12 is specifically an elliptical or flat groove structure. The inlet pipe 11 and the outlet pipe 12 are made of titanium alloy or aluminum alloy. Threaded grooves can be provided at the port positions of the inlet pipe 11 and the outlet pipe 12 to facilitate the connection of the inlet pipe 11 and the outlet pipe 12.
[0073] In this embodiment, the fluid processing mechanism 5 includes:
[0074] The fluid processing mechanism support 51 is detachably installed in the purification chamber 111 and is used to support the fluid processing mechanism 5.
[0075] The processing mechanism support 51 is specifically a round or rectangular structure, and its interior is hollow. A support plate is provided at its bottom to support the fluid filtration assembly 6.
[0076] The fluid filtration assembly 6 is installed on the processing mechanism support 51 and is used for fluid filtration and purification.
[0077] The fluid processing assembly 55, which is installed on the processing mechanism support 51, is used to process harmful substances flowing into the purification chamber 111 and works in conjunction with the fluid filtration assembly 6.
[0078] In this embodiment, during operation, the inlet pipe 11 and the outlet pipe 12 are fixedly connected, and one end of the inlet pipe 11 is installed at the outlet position of the fluid transmission. When the fluid enters, the impurities generated can be purified by the fluid filtration component 6 and the fluid processing component 55. The clean fluid is discharged through the outlet pipe 12, avoiding fluid pollution of the external environment.
[0079] The present invention discloses a fluid processing mechanism 5, which includes a processing mechanism support 51, a fluid filtration assembly 6, and a fluid processing assembly 55 that works in conjunction with the fluid filtration assembly 6. The fluid processing assembly 55 can process and absorb harmful substances in the fluid, ensuring the cleanliness of the fluid, and the fluid filtration assembly 6 can filter impurities in the fluid.
[0080] In a further preferred embodiment of the present invention, such as Figure 6-9 As shown, the fluid processing mechanism 5 further includes a support adjustment assembly for adjusting the position of the processing mechanism support 51, the support adjustment assembly including:
[0081] At least one set of support adjustment grooves 52 is provided in the support seat 51 of the processing mechanism;
[0082] A support drive unit 53 is installed within the support adjustment groove 52. The support drive unit 53 has at least one set of...
[0083] The other end of the support drive unit 54 is connected to the support drive unit 53 and the liquid inlet pipe 11 is connected to the support drive unit 54.
[0084] In this embodiment, the support adjustment groove 52 is a rectangular groove or a circular groove, and the support adjustment groove 52 is arranged circumferentially about the processing mechanism support seat 51 to ensure the stability of the processing mechanism support seat 51 and prevent it from shaking or falling off during operation.
[0085] In this embodiment, the support drive part 53 is an internally threaded sleeve, and the support transmission part 54 is a threaded rod. One end of the support drive part 53 is rotatably connected to the liner adjustment groove through a bearing, and one end of the support transmission part 54 extends into the support drive part 53. The other end of the support transmission part 54 is fixedly installed by bolts or buckles. When it is necessary to adjust the position of the processing mechanism support seat 51, the support drive part 53 is rotated, and the relative displacement between the support drive part 53 and the support transmission part 54 is achieved, thereby realizing the adjustment of the position of the processing mechanism support seat 51.
[0086] In another embodiment of the present invention, the support drive unit 53 is specifically a servo hydraulic cylinder or an electric push rod, and the telescopic end of the support drive unit 53 is fixedly connected to the support transmission unit 54 by fastening bolts. The support transmission unit 54 is a horizontal slide bar or a horizontal sliding plate structure.
[0087] In a further preferred embodiment of the present invention, such as Figure 6-9 As shown, the fluid filtration assembly 6 includes:
[0088] The fluid purification mechanism includes a purification mechanism mounting base 61, which is detachably mounted on the processing mechanism support base 51. A fluid filtration section is provided inside the purification mechanism mounting base 61 for filtering the discharged fluid.
[0089] The purification and anti-clogging mechanism 7 is located on one side of the fluid purification mechanism and installed in the processing mechanism support 51 to prevent the fluid purification mechanism from becoming clogged.
[0090] In this embodiment, during operation, the fluid purification mechanism and the purification anti-clogging mechanism 7 work together to prevent clogging of the fluid purification mechanism, ensuring smooth fluid processing and improving fluid processing efficiency. Meanwhile, in this embodiment, the purification mechanism mounting base 61 is specifically a slot or seat structure, which is horizontally set and installed by fastening bolts or buckles. The fluid filtration section is specifically an activated carbon filter screen, activated carbon filter box, and fiber filter screen structure. The fluid filtration section can purify and deodorize the fluid.
[0091] In a further preferred embodiment of the present invention, such as Figure 6-9 As shown, the purification and anti-clogging mechanism 7 includes:
[0092] Anti-clogging component 77 is disposed on one side of the fluid purification mechanism to prevent clogging of the fluid purification mechanism;
[0093] An anti-clogging drive assembly is installed in the processing mechanism support 51 and connected to the anti-clogging assembly 77 for adjusting the position of the anti-clogging assembly 77.
[0094] In this embodiment, during operation, the anti-clogging drive component is activated, which drives the anti-clogging component 77 to move, thereby enabling the anti-clogging component 77 to scrape and clean the fluid purification mechanism, avoiding the accumulation of impurities and improving filtration efficiency.
[0095] In a further preferred embodiment of the present invention, such as Figure 6-7 As shown, the anti-clogging drive component includes:
[0096] The anti-clogging drive unit 71 is fixedly installed inside the processing mechanism support 51;
[0097] An anti-clogging transmission part 72 is fixedly connected to the anti-clogging drive part 71, and an anti-clogging driven part 73 is provided on one side of the anti-clogging transmission part 72 to cooperate with it.
[0098] An anti-clogging rotating part 74 is fixedly connected to the anti-clogging driven part 73, and the anti-clogging rotating part 74 is provided on one side of the anti-clogging driven part 73.
[0099] In this embodiment, the anti-clogging drive unit 71 is specifically a hydraulic cylinder, a pneumatic cylinder, or an electric push rod, and one end of the anti-clogging transmission unit 72 is fixedly connected to the anti-clogging drive unit 71 through a connecting clamp. The anti-clogging transmission unit 72 is a horizontal gear, and the anti-clogging driven unit 73 is specifically a gear. The anti-clogging transmission unit 72 and the anti-clogging driven unit 73 mesh and transmit power.
[0100] To further prevent clogging of the fluid purification mechanism, one end of the anti-clogging transmission part 72 extends into the air circulation chamber. A piston plate is slidably installed in the air circulation chamber and is fixedly connected to the anti-clogging transmission part 72. A circulation port is opened on one side of the air circulation chamber to release air, further preventing clogging of the fluid purification mechanism.
[0101] Meanwhile, in this embodiment of the invention, one end of the anti-clogging transmission part 72 extends into the air circulation chamber, realizing the linkage transmission of power to the anti-clogging drive part 71, thereby achieving energy saving and avoiding clogging of the fluid purification mechanism.
[0102] In a further preferred embodiment of the present invention, such as Figure 6-7 As shown, the anti-clogging drive component also includes:
[0103] An active pusher 75 is mounted on the anti-clogging rotating part 74 and is used for the transmission of power between the anti-clogging rotating part 74 and the anti-clogging drive part 71.
[0104] A driven pusher 76 is connected to the active pusher 75 and is fixedly connected to the anti-clogging component 77 for adjusting the position of the anti-clogging component 77.
[0105] In this embodiment, the anti-clogging rotating part 74 is fixedly connected to the anti-clogging driven part 73 via a connecting rod. The active pusher 75 and the driven pusher 76 are specifically hinged rods that are hinged to each other, and the other end of the active pusher 75 is hinged to the anti-clogging rotating part 74.
[0106] When the fluid purification mechanism needs to be cleaned during operation to prevent blockage, the anti-blockage drive unit 71 is activated. The anti-blockage drive unit 71 drives the anti-blockage transmission unit 72 to move. The anti-blockage transmission unit 72 drives the anti-blockage driven unit 73 and the anti-blockage rotating unit 74 to rotate. The anti-blockage rotating unit 74 drives the active pusher 75 and the driven pusher 76 to move, thereby realizing the adjustment of the position of the anti-blockage component 77.
[0107] In a further preferred embodiment of the present invention, such as Figure 6-8As shown, the anti-clogging component 77 includes:
[0108] A movable anti-clogging mounting bracket 771 is provided, and multiple sets of anti-clogging limiting grooves are installed on the anti-clogging mounting bracket 771.
[0109] At least one set of anti-clogging components 772 are installed in the anti-clogging limit groove to clean the fluid purification mechanism and prevent the fluid purification mechanism from becoming clogged.
[0110] In this embodiment, the anti-clogging mounting bracket 771 specifically includes a mounting upright plate and a mounting horizontal plate fixedly connected to the mounting upright plate. The mounting horizontal plate and the mounting upright plate are fixedly connected by bolts or rivets. The surfaces of the mounting horizontal plate and the mounting upright plate are polished to prevent the adsorption of impurities.
[0111] In this embodiment, the anti-clogging component 772 is an elastic protrusion, and the anti-clogging component 772 is elastically connected to the anti-clogging limiting groove. Specifically, the elastic connection between the two is achieved by an elastic sheet or a spring connection, so that when the anti-clogging component 772 comes into contact with the fluid filtration section, it shakes off the impurities adsorbed on its surface, thereby improving the filtration efficiency of the fluid filtration section.
[0112] In a further preferred embodiment of the present invention, such as Figure 6-9 As shown, the fluid processing assembly 55 includes:
[0113] At least one set of fluid processing units, said fluid processing units being installed within the processing mechanism support 51, and said fluid processing units comprising:
[0114] Main processing unit 552;
[0115] An auxiliary processing component 554 is fixedly connected to the main processing component 552, and both the main processing component 552 and the auxiliary processing component 554 have multiple sets of fluid processing tanks 553. The fluid processing tanks 553 are used to purify the fluid, treat harmful substances in the fluid, and
[0116] The processing unit drive unit 551 is used to adjust the position of the main processing unit 552 and the auxiliary processing unit 554, and the processing unit fixing unit is fixedly installed in the processing mechanism support 51.
[0117] In this embodiment, the main processing component 552 and the auxiliary processing component 554 are arranged circumferentially about the processing mechanism support 51. Alternatively, they can be arranged alternately. The main processing component 552 is an arc-shaped or fan-shaped plate structure, and the auxiliary processing component 554 is an irregular polygonal structure to increase the contact area with the fluid. The processing component drive unit 551 is specifically a servo motor, and the output end of the processing component drive unit 551 is interference-fitted with the main processing component 552. The fluid processing tank 553 is specifically an arc-shaped tank, a circular tank, or a rectangular tank, and an oxidation catalyst DOC carrier for oxidizing harmful substances in the fluid is fixedly installed in the fluid processing tank 553. The oxidation catalyst DOC carrier can oxidize carbon monoxide and hydrocarbons, preventing harmful substances from being discharged and harming the external environment.
[0118] In a further preferred embodiment of the present invention, such as Figure 1 and 6 As shown, this embodiment of the invention also includes a detachable fluid silencing mechanism 3 for collecting impurities in the fluid. The fluid silencing mechanism 3 includes:
[0119] At least one set of silencer mechanism mounting base 31 is detachably installed inside the liquid inlet pipe 11;
[0120] The fluid silencing component 32 is installed on the silencing mechanism mounting base 31. The fluid silencing component 32 is used to silence the flow of fluid.
[0121] In this embodiment, the silencing mechanism mounting base 31 is circumferentially arranged on the liquid inlet pipe 11. The silencing mechanism mounting base 31 and the liquid inlet pipe 11 are connected by a snap-fit, which facilitates disassembly and cleaning. A sealing gasket is provided at the connection between the two. The fluid silencing component 32 is specifically a sound-absorbing cotton or a silencer. The setting of the fluid silencing component 32 facilitates the silencing of fluid flow, while increasing the contact area with the fluid and improving the silencing efficiency.
[0122] In a further preferred embodiment of the present invention, such as Figure 10-13 As shown, this embodiment of the invention also includes an electromagnetic adjustment mechanism 2 for adapting to different fluid flow rate requirements, used to change the fluid discharge flow rate. The electromagnetic adjustment mechanism 2 includes:
[0123] The power supply base 27 is fixedly connected to the liquid inlet pipe, and a valve chamber is provided inside the power supply base 27, which is in continuous communication with the purification chamber.
[0124] Electromagnetic housing 21 is disposed on one side of the power supply base 27;
[0125] A magnetic base 23 is embedded at one end of the electromagnetic housing 21. A magnetic induction base 22 is fixedly connected to one side of the magnetic base 23. A magnetic induction coil 221 is wound inside the magnetic induction base 22. The magnetic induction coil 221 is electrically connected to the power supply base 27.
[0126] A moving iron core 26 is provided in the magnetic base 22, and a fixed iron core is provided on one side of the moving iron core 26. The moving iron core 26 is slidably connected to the electromagnetic housing 21. A sealing ring 25 for limiting the position of the moving iron core 26 is provided in the electromagnetic housing 21, and a return spring 24 is fixedly embedded on one side of the moving iron core 26. A valve body core assembly 4 is detachably connected to the other side of the moving iron core 26. The valve body core assembly 4 is used to open or close the drain pipe 12. The valve body core assembly 4 is movably installed in the valve cavity.
[0127] The valve body core assembly 4 includes:
[0128] Valve stem 41, one end of which is detachably connected to the moving iron core 26;
[0129] A valve disc 42 is installed at the end of the valve stem 41, and the valve disc 42 is used to open or close the valve chamber 43.
[0130] During operation, a storage battery is fixedly installed inside the power supply base 27, which energizes the magnetic induction coil 221. This causes the magnetic induction coil 221 to DC drive the moving iron core 26 to move, which in turn causes the moving iron core 26 to slide along the sealing ring 25. This allows the moving iron core 26 to drive the valve body core assembly 4, thereby opening or closing the valve chamber 43. At the same time, depending on the position of the valve disc 42, the fluid flow rate can be adjusted, and the fluid flow does not need to be reversed multiple times to open or close the drain pipe 12, avoiding damage to the valve body core assembly 4. When the magnetic induction coil 221 is de-energized, the restoring force of the return spring 24 acts on the moving iron core 26, causing the moving iron core 26 to drive the valve disc 42 in the valve body core assembly 4 to close the valve chamber 43.
[0131] Meanwhile, in order to facilitate the installation of the energy-saving fluid control solenoid valve, a main mounting base 13 is fixedly sleeved on the outer wall of the inlet pipe 11. The main mounting base 13 has multiple sets of installation auxiliary grooves 131, which are circular threaded grooves to facilitate the fixed installation of the inlet pipe 11.
[0132] In summary, the present invention provides an energy-saving fluid control solenoid valve. The embodiments of the present invention disclose a fluid processing mechanism 5, which includes a processing mechanism support 51, a fluid filter assembly 6, and a fluid processing component 55 that works in conjunction with the fluid filter assembly 6. The fluid processing component 55 can process and absorb harmful substances in the fluid, ensuring the cleanliness of the fluid, and the fluid filter assembly 6 can filter impurities in the fluid.
[0133] Meanwhile, in this embodiment of the invention, an electromagnetic adjustment mechanism 2 is provided to adapt to different fluid flow requirements. The electromagnetic adjustment mechanism 2 can adjust the fluid flow, and the fluid flow does not need to be reversed multiple times to open or close the drain pipe 12, thus avoiding damage to the valve body core assembly 4. When the magnetic coil 221 is de-energized, the restoring force of the reset spring 24 acts on the moving iron core 26, causing the moving iron core 26 to drive the valve disc 42 in the valve body core assembly 4 to close the valve cavity 43.
[0134] It should be noted that, for the sake of simplicity, the foregoing embodiments are all described as a series of actions. However, those skilled in the art should understand that the present invention is not limited to the described order of actions, as some steps may be performed in other orders or simultaneously according to the present invention. Furthermore, those skilled in the art should also understand that the embodiments described in the specification are preferred embodiments, and the actions and modules involved are not necessarily essential to the present invention.
[0135] The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to limit the scope of protection of the invention. Obviously, the described embodiments are only some embodiments of the present invention, not all embodiments. Based on these embodiments, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention. Although the present invention has been described in detail with reference to the above embodiments, those skilled in the art can still combine, add, delete, or otherwise adjust the features of the various embodiments of the present invention according to the circumstances without conflict or creative effort, thereby obtaining different technical solutions that do not fundamentally depart from the concept of the present invention. These technical solutions also fall within the scope of protection of the present invention.
Claims
1. An energy-saving fluid control solenoid valve, characterized in that, The energy-saving fluid control solenoid valve includes: The solenoid valve body includes an inlet pipe and a drain pipe connected to the inlet pipe. The inlet pipe and the drain pipe are connected through an electromagnetic adjustment mechanism, and a purification chamber is formed at the connection between the inlet pipe and the electromagnetic adjustment mechanism. A detachable fluid handling mechanism is installed inside the purification chamber, which is used for fluid filtration and purification. The fluid handling mechanism includes: The fluid handling mechanism support is detachably installed inside the purification chamber to support the fluid handling mechanism. A fluid filtration assembly, mounted on a support of the processing unit, is used for the filtration and purification of fluids. The fluid treatment component, installed on the support of the treatment mechanism, is used to treat harmful substances flowing into the purification chamber and works in conjunction with the fluid filtration component. The fluid filtration assembly includes: A fluid purification mechanism includes a purification mechanism mounting base, which is detachably mounted on a processing mechanism support base, and a fluid filtration section is provided inside the purification mechanism mounting base for filtering the discharged fluid. The purification and anti-clogging mechanism is located on one side of the fluid purification mechanism and installed in the treatment mechanism support to prevent clogging of the fluid purification mechanism. The purification and anti-clogging mechanism includes: An anti-clogging component is located on one side of the fluid purification mechanism to prevent clogging of the fluid purification mechanism; An anti-clogging drive assembly is installed in the support of the processing mechanism and connected to the anti-clogging assembly for adjusting the position of the anti-clogging assembly; The fluid processing assembly includes: At least one set of fluid processing units, said fluid processing units being installed within a processing mechanism support, and said fluid processing units comprising: Main processing component; An auxiliary processing unit is fixedly connected to the main processing unit, and both the main processing unit and the auxiliary processing unit have multiple sets of fluid processing tanks. These fluid processing tanks are used to purify the fluid, treat harmful substances in the fluid, and... The processing unit drive unit is used to adjust the position of the main processing unit and the auxiliary processing unit, and the processing unit fixing unit is fixedly installed in the processing mechanism support.
2. The energy-saving fluid control solenoid valve as described in claim 1, characterized in that, The fluid processing mechanism further includes a support adjustment assembly for adjusting the position of the support seat of the processing mechanism, the support adjustment assembly comprising: At least one set of support and adjustment grooves is provided inside the support seat of the processing mechanism; A support drive unit installed in the support adjustment groove, wherein the support drive unit is provided with at least one set, and The support drive unit is connected to the support drive unit, and the other end of the support drive unit is connected to the liquid inlet pipe.
3. The energy-saving fluid control solenoid valve as described in claim 2, characterized in that, The anti-clogging drive component includes: The anti-clogging drive unit is fixedly installed inside the processing mechanism support; An anti-clogging transmission unit is fixedly connected to the anti-clogging drive unit, and an anti-clogging driven unit that works in conjunction with the anti-clogging transmission unit is provided on one side of the anti-clogging transmission unit. An anti-clogging rotating part is fixedly connected to the anti-clogging driven part, and the anti-clogging rotating part is provided on one side of the anti-clogging driven part.
4. The energy-saving fluid control solenoid valve as described in claim 3, characterized in that, The anti-clogging drive component also includes: An active actuating component is installed on the anti-clogging rotating part and is used for the transmission of power between the anti-clogging rotating part and the anti-clogging driving part; A driven pusher is connected to the active pusher, and the driven pusher is fixedly connected to the anti-clogging component for adjusting the position of the anti-clogging component.
5. The energy-saving fluid control solenoid valve as described in claim 4, characterized in that, The anti-clogging component includes: A movable anti-clogging mounting bracket, and multiple anti-clogging limit grooves are installed on the anti-clogging mounting bracket; At least one set of anti-clogging components is installed in the anti-clogging limit groove to clean the fluid purification mechanism and prevent it from becoming clogged.
6. An energy-saving fluid control solenoid valve as described in any one of claims 2-5, characterized in that, It also includes a detachable fluid silencing mechanism for collecting impurities in the fluid, the fluid silencing mechanism comprising: At least one set of silencer mounting brackets is detachably installed inside the liquid inlet pipe; A fluid silencing component installed on a silencing mechanism mounting base; the fluid silencing component is used to silence the flow of fluid.
7. An energy-saving fluid control solenoid valve as described in any one of claims 2-5, characterized in that, It also includes an electromagnetic regulating mechanism for adapting to different fluid flow rate requirements, used to change the fluid discharge flow rate, the electromagnetic regulating mechanism comprising: A power supply base is fixedly connected to the liquid inlet pipe, and a valve chamber is provided inside the power supply base, which is in continuous communication with the purification chamber; An electromagnetic housing disposed on one side of the power supply base; A magnetic base is embedded at one end of the electromagnetic housing. A magnetic induction base is fixedly connected to one side of the magnetic base. A magnetic induction coil is wound inside the magnetic induction base. The magnetic induction coil is electrically connected to the power supply base. A moving iron core is set in the magnetic induction base. The moving iron core is slidably connected to the electromagnetic housing. A sealing ring for limiting the movement of the moving iron core is provided in the electromagnetic housing. A return spring is fixedly embedded on one side of the moving iron core. A valve body core assembly is detachably connected to the other side of the moving iron core. The valve body core assembly is used to open or close the drain pipe. The valve body core assembly is movably installed in the valve cavity. The valve body core assembly includes: A valve stem, one end of which is detachably connected to a moving iron core; A valve disc mounted at the end of a valve stem, the valve disc being used to open or close the valve chamber.