CN114811712A - Magnetic suspension floating valve radiator and temperature control device thereof - Google Patents

Abstract

The application discloses magnetic suspension floats valve radiator and temperature control device thereof, wherein, temperature control device (10) include magnetic pole (11), float valve (12) and driving piece (13), the valve interval ground cover that floats is established on the magnetic pole, float the valve have with the inboard magnetic part that the magnetic pole is adjacent with keep away from the outside magnetic part of magnetic pole, inboard magnetic part with the magnetic pole produces repellent magnetic force each other, makes the valve that floats for the magnetic pole suspension, the driving piece be the magnetic part and can with the outside magnetic part produces the magnetic force of attracting each other. The floating valve can suspend through repulsion with the magnetic pole to can remove along with the removal of driving piece under the effect of the magnetic attraction of the outside driving piece of radiator, make the floating valve can remove in the inlet tube of radiator along the magnetic pole, with the quantity of the water supply union coupling of the flow through heat medium of adjusting the radiator, thereby realize the temperature regulation of radiator.

Description

Magnetic suspension floating valve radiator and temperature control device thereof

Technical Field

The application relates to heating equipment, in particular to a magnetic suspension floating valve radiator and a temperature control device thereof.

Background

The radiator heating system is a common heating system, and the radiator is required to have an automatic temperature adjusting function along with the improvement of the requirements on energy conservation and indoor comfort. In the prior art, a temperature control valve is usually additionally arranged at a heat medium inlet of a radiator, and the heat dissipation capacity is adjusted by changing the flow of the heat medium entering the radiator. The adjustment modes are all throttling type, have larger resistance and are not suitable for a gravity circulating heating system. And because the temperature control valve sets up on the pipeline of the connection radiator of heating system, long-term operation leads to the water pump of heating system to carry the energy consumption high, and energy-conservation nature is poor. In addition, because need install the temperature-sensing valve additional, need extra construction and expense, according to different heating systems, probably still need carry out system transformation moreover. In addition, the heat medium is usually hot water with low water quality, and the temperature control valve is easy to block due to poor water quality after long-term use, so that the maintenance cost is high.

Therefore, how to reduce energy consumption, construction and maintenance costs while achieving temperature regulation becomes a technical problem to be solved in the field.

Disclosure of Invention

In view of this, the present application provides a temperature control device for a heat sink, so as to reduce energy consumption, construction and maintenance costs while achieving temperature adjustment.

According to the application, a temperature control device of magnetic suspension float valve radiator is proposed, wherein, temperature control device includes magnetic pole, float valve and driving piece, the cover is established at the float valve interval on the magnetic pole, the float valve have with the inboard magnetic part that the magnetic pole is adjacent with keep away from the outside magnetic part of magnetic pole, inboard magnetic part with the magnetic pole produces repellent magnetic force each other, makes the float valve for the magnetic pole suspends, the driving piece be the magnetic part and can with the outside magnetic part produces the magnetic force of attracting each other.

Optionally, the magnetic rod is configured to be inserted into a water inlet pipe of a radiator, and the cross section of the floating valve is configured to match with the through-flow cross section of the water inlet pipe.

Optionally, the float valve comprises an inner magnetic ring forming the inner magnetic part, an outer magnetic ring forming the outer magnetic part, and a connecting ring connecting the inner magnetic ring and the outer magnetic ring, wherein the connecting ring is a light member with density not greater than water.

Optionally, the float valve is a ring shape with constant axial and radial dimensions, wherein: the average density of the floating valve is 0.96kg/L-1 kg/L.

Optionally, the diameter of the magnetic rod is 8-12mm, and the floating valve is arranged to be spaced from the magnetic rod by 2-4 mm.

Optionally, the floating valve has an extension thickness of 18mm to 22mm along the axial direction of the magnetic rod.

The application still provides a magnetic suspension valve radiator that floats, wherein, the magnetic suspension valve radiator that floats includes the temperature control device of this application, supplies water the union coupling and is located the end cap at water supply union coupling both ends, the magnetic pole with the valve that floats is followed the one end of supplying water the union coupling stretches into the water supply union coupling passes through the end cap is fixed in the water supply union coupling, the driving piece sets up the water supply union coupling outside can be followed the axial displacement of water supply union coupling.

Optionally, the radiator is provided with a groove extending in the axial direction of the water supply header, and the driving member is slidably disposed in the groove.

Optionally, the bottom surface of the groove is an outer wall of the water supply header.

Optionally, the radiator includes a plurality of radiating pipes communicating with the water supply header, and the length of the magnetic rod is set to allow the float valve to pass through all of the radiating pipes.

According to the technical scheme of this application, the valve that floats can suspend through the repulsion with the magnetic pole to can remove along with the removal of driving piece under the effect of the magnetic attraction of the outside driving piece of radiator, make the valve that floats can follow the magnetic pole and remove in the water supply union pipe of radiator, with the quantity of the cooling tube of the thermal medium of crossing of adjusting the radiator, thereby realize the temperature regulation of radiator.

Additional features and advantages of the present application will be described in detail in the detailed description which follows.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate an embodiment of the invention and, together with the description, serve to explain the invention. In the drawings:

FIG. 1 is a cross-sectional view of a heat sink according to a preferred embodiment of the present application;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

FIG. 3 is a side cross-sectional view of the position of the float valve of FIG. 1;

fig. 4 is a partially enlarged view of a portion B in fig. 3.

Detailed Description

The technical solutions of the present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

According to an aspect of the present application, a temperature control device (hereinafter referred to as temperature control device) of a heat sink is provided, wherein, temperature control device 10 includes a magnetic rod 11, a floating valve 12 and a driving member 13, the floating valve 12 is sleeved on the magnetic rod 11 at intervals, the floating valve 12 has an inner magnetic portion adjacent to the magnetic rod 11 and an outer magnetic portion away from the magnetic rod 11, the inner magnetic portion and the magnetic rod 11 generate repulsive magnetic force with each other, so that the floating valve 12 floats with respect to the magnetic rod 11, the driving member 13 is a magnetic member and can generate attractive magnetic force with the outer magnetic portion.

According to another aspect of the present application, there is provided a heat sink, wherein the heat sink 100 comprises the temperature control device 10 of the present application, a water supply header 20 and plugs 30 at two ends of the water supply header 20, the magnetic rod 11 and the floating valve 12 extend from one end of the water supply header 20 into the water supply header 20 and are fixed in the water supply header 20 through the plugs 30, and the driving member 13 is disposed outside the water supply header 20 and can move along the axial direction of the water supply header 20.

In the present application, the magnetic force of the float valve 12 and the magnetic rod 11 repel each other, so that the float valve 12 receives the repulsive force symmetrical with respect to the axial direction of the magnetic rod 11, and thus can be kept in levitation with respect to the magnetic rod 11. And the magnetic force line of the driving part 13 can pass through the water supply connecting pipe 20 and act on the floating valve 12, the floating valve 12 can move along with the movement of the driving part 13 under the action of the magnetic attraction force of the driving part 13 outside the radiator shell, so that the floating valve 12 can move in the water supply connecting pipe 20 of the radiator 100 along the magnetic rod 11, the number of the radiating pipes of the radiator, which flow through the heat medium, is adjusted, and the temperature of the radiator is adjusted.

Specifically, as shown in fig. 1, the radiator 100 includes a plurality of radiating pipes 50 communicated with the water supply header 20, the radiator 100 further includes a water return header 60, the plurality of radiating pipes 50 are respectively communicated with the water return header 60, and the heat medium enters through the water inlet 101 of the water supply header 20, flows into the water return header 60 through the radiating pipes 50, and flows out through the water outlet 102. The magnetic rod 11 is configured to be inserted into the water supply pipe 20 of the heat sink (the floating valve 12 sleeved on the magnetic rod 11 can be inserted into the water supply pipe 20 together with the water supply pipe) so that the magnetic rod 11 is positioned in the water supply pipe 20 (for example, the end of the magnetic rod 11 can be fixed to the plug 30), for example, the magnetic rod 11 is parallel to or coincides with the axis of the water supply pipe 20, so that when the driving member 13 moves in the axial direction of the water supply pipe 20 outside the water supply pipe 20 (i.e., outside the heat sink housing), the magnetic rod 11 can drive the floating valve 12 to move along the magnetic rod 11 by overcoming the resistance of the heat medium through the magnetic attraction force. When the floating valve 12 is moved to a different position of the magnetic rod 11, the floating valve 12 will serve as a boundary of the radiating pipe 50 in which the heat medium flows or not. Specifically, in the embodiment shown in fig. 1, the heat medium flows through only the heat pipe 50 on the right side of the floating valve 12 and then flows into the return water header 60 and flows out through the water outlet 102, and does not substantially flow through the heat pipe 50 on the left side of the floating valve 12. By moving the floating valve 12 and changing the position of the floating valve relative to the magnetic rod 11, the number of the radiating pipes 50 in which the thermal medium flows can be adjusted, and the temperature of the radiator can be adjusted.

It can be understood that, since the floating valve 12 floats with respect to the magnetic rod 11, there is no contact between the floating valve 12 and the magnetic rod 11, and there is no friction therebetween, so that the magnetic attraction force between the driving member 13 and the floating valve 12 only needs to overcome the resistance of the heat medium for the movement of the floating valve 12 along the magnetic rod 11, and the floating valve 12 can easily move freely in the water supply connecting pipe 20. Further, the farther the float valve 12 is from the water inlet 101 of the water supply connecting pipe 20, the smaller the flow velocity of the heat medium at the position of the float valve 12, and the less the heat medium hinders the movement of the float valve 12, so that the float valve 12 can be always driven by the driving member 13. In addition, by blocking the heat medium at the communication position of the heat dissipation pipe 50 and the water supply union pipe 20, the resistance of the floating valve 12 to the heat medium is small, so that the resistance loss is reduced compared with the existing temperature control valve, and the pumping energy consumption of the functional system is reduced. Further, since the float valve 12 is provided in the water supply pipe 20 of the radiator, the water supply pipe 20 has a larger cross section than the pipe of the heating system near the radiator, and is less likely to be clogged even if the water quality of the heating medium is not high.

In order to ensure the above-described boundary action of the float valve 12, the float valve 12 is to be able to substantially block the flow cross section of the water supply connection 20. That is, the cross section of the float valve 12 is configured to match the flow cross section of the water supply pipe 20, and specifically, the outer contour of the float valve 12 may be configured to be slightly smaller than the inner wall contour of the water supply pipe 20. For example, the float valve 12 may be annular and may have an outer diameter slightly smaller (e.g., 2mm to 5mm smaller) than the inner diameter of the water supply header 20. Therefore, the heat medium flows through only the heat pipe 50 on one side of the float valve 12, and the heat medium does not substantially flow through the heat pipe 50 on the other side (even if a small amount of heat medium flows through the gap between the float valve 12 and the magnetic rod 11, the heat dissipation effect of the radiator is not substantially affected).

As described above, the float valve 12 can be suspended relative to the magnetic rod 11 by magnetic repulsion with the magnetic rod 11 and can move therewith by magnetic attraction with the driving member 13. The float valve 12 should be arranged so that the inner magnetic part and the mutually opposing surface of the magnetic lever 11 have the same polarity and so that the outer magnetic part and the mutually opposing surface of the driver 13 have the opposite polarity. The magnetic rod 11 and the driving member 13 may be both magnetic members, or magnetic layers may be disposed at corresponding positions.

According to one embodiment of the present application, the float valve 12 may be an integral magnetic member (e.g., a permanent magnet), and the polarity of the inner magnetic portion and the outer magnetic portion are opposite, and the polarity of the outer surface of the magnetic rod 11 and the surface of the driving member 13 that interacts with the outer magnetic portion are the same.

According to another embodiment of the present application, as shown in fig. 2 and 4, the float valve 12 includes an inner magnetic ring 121 forming the inner magnetic portion, an outer magnetic ring 122 forming the outer magnetic portion, and a connection ring 123 connecting the inner magnetic ring 121 and the outer magnetic ring 122, the connection ring 123 being a lightweight member having a density not greater than water. Thereby, the self weight of the float valve 12 can be reduced and the buoyancy thereof can be increased by the connection ring 123, so that the float valve 12 can be suspended. In this case, the outer surface of the magnetic rod 11 and the inner surface of the inner magnet ring 121 are of the same polarity, and the outer surface of the outer magnet ring 122 and the surface of the driver 13 that interacts with the outer surface of the outer magnet ring 122 are of opposite polarity.

The connection ring 123 may be, for example, a plastic or rubber member, and the inner magnetic ring 121 and the outer magnetic ring 122 are both magnetic members (e.g., permanent magnets). The inner magnetic ring 121 and the outer magnetic ring 122 are preferably made of a corrosion-resistant magnetic material, and may be in long-term contact with a thermal medium (e.g., water), or an anti-corrosion layer may be disposed on outer surfaces of the inner magnetic ring 121 and the outer magnetic ring 122.

The connection ring 123 may be connected between the inner magnetic ring 121 and the outer magnetic ring 122 by any suitable means, for example, may be filled between the inner magnetic ring 121 and the outer magnetic ring 122 by injection molding, extrusion, or the like, or may connect the outer surface of the inner magnetic ring 121 and the inner surface of the outer magnetic ring 122 by adhesion or the like.

In this application, the float valve 12 is a ring-shaped member to be fitted over the magnetic rod 11. Specifically, the float valve 12 may have a ring shape with various suitable cross sections. As described above, in order to facilitate blocking of the thermal medium, the cross section of the float valve 12 is preferably identical to the through-flow section of the water supply header 20, i.e., the float valve 12 is preferably annular. In order to provide the entire float valve 12 with uniform resistance against the heat medium, the float valve 12 is preferably annular with a constant axial and radial dimension. In order to take account of the resistance to the heat medium and the suspension capacity, the average density of the floating valve 12 is equivalent to that of water, and may specifically be 0.96kg/L to 1kg/L, which may be achieved by selecting an inner magnetic ring 121, an outer magnetic ring 122, and a connection ring 123 of appropriate materials and sizes. In the embodiment shown in fig. 1 to 4, the inner and outer magnetic rings 121 and 122 are magnets, the connection ring 123 is made of plastic or rubber, the inner diameter of the inner magnetic ring 121 may be 25mm to 30mm, the outer diameter of the inner magnetic ring 121 may be 60mm to 70mm, the inner diameter of the outer magnetic ring 122 may be 200mm to 220mm, the outer diameter of the outer magnetic ring 122 may be 220mm to 240mm, the inner diameter of the connection ring 123 may be 60mm to 70mm, and the outer diameter of the connection ring 123 may be 200mm to 220 mm.

In order to ensure that there is enough repulsive force between the floating valve 12 and the magnetic rod 11 to maintain the suspension and avoid the problem that the suspension distance is too large to provide enough resistance to the heat medium, the distance between the floating valve 12 and the magnetic rod 11 should be set reasonably according to the size of the magnetic rod 11. Preferably, the diameter of the magnetic rod 11 may be 8-12mm, and the float valve 12 may be disposed at a distance of 2-4 mm from the magnetic rod 11.

In addition, the float valve 12 should have a suitable thickness to provide sufficient resistance to the heat medium, and at the same time, facilitate the driving by the driving member 13. Preferably, the floating valve 12 may have an extension thickness of 18mm to 22mm in the axial direction of the magnetic rod 11.

The driving member 13 may be disposed at any suitable position outside the water supply connection 20 as long as it can freely move in the axial direction of the water supply connection 20. In order to facilitate the positioning of the driving member 13 so that it can remain relatively fixed after the float valve 12 is moved to a desired position, thereby positioning the float valve 12, it is preferred that the radiator 100 is provided with a groove 40 extending in the axial direction of the water supply header 20, and the driving member 13 is slidably disposed in the groove 40. Thus, after the float valve 12 has been moved to the desired position, the drive member 13 can be retained in the corresponding position within the recess 40 to position the float valve 12.

The groove 40 may be disposed at a suitable position of the radiator 100, as long as it can correspond to the axial extension of the water supply connecting pipe 20, facilitate the magnetic force lines of the driving member 13 to pass through to interact with the floating valve 12, and facilitate the position of the driving member 13 to be maintained. The water supply header 20 is typically located at the top of the heat sink 100 and the recess 40 may be located at the top of the heat sink 100, such as at the top or top side of the heat sink 100. To facilitate the stable retention of the driver 13 in the recess 40, the driver 13 may be in the form of a block.

To ensure the magnetic attraction of the driver 13 to the float valve 12, the magnetic lines of force of the driver 13 should be oriented as perpendicular as possible to the outer surface of the float valve 12. To this end, the bottom surface of the groove 40 may be an outer wall of the water supply header. Preferably, as shown in fig. 2 and 3, the surface of the driving member 13 corresponding to the bottom surface of the groove 40 is a cambered surface matched with the bottom surface.

In addition, in order to increase the temperature adjustment range of the radiator 100, the float valve 12 can be moved as far as possible along the water supply connecting pipe 20. Preferably, the magnetic rod 11 has a length that allows the floating valve 12 to pass through all the radiating pipes 50, so that the temperature of the radiator 100 can be adjusted by the floating valve 12 between a maximum radiating state in which the heat medium is allowed to flow through all the radiating pipes 50 and a minimum radiating state in which the hot water is not substantially allowed to flow therethrough.

The temperature control device of this application is convenient for set up (only need insert magnetic pole 11 and floating valve 12 from the one end of water supply header 20), convenient to use (only need remove driving piece 13 from the outside), can conveniently install additional in the heating pipe-line system who already exists, is suitable for gravity circulation's heating system.

The preferred embodiments of the present application have been described in detail, but the present application is not limited to the details of the above embodiments, and various simple modifications (for example, the float valve 12 may be a complete ring or a ring with a notch) may be made to the technical solution of the present application within the technical idea of the present application, and all of these simple modifications belong to the protection scope of the present application.

It should be noted that, in the foregoing embodiments, various features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various possible combinations are not described in the present application.

In addition, any combination of the various embodiments of the present application can be made, and the same should be considered as the disclosure of the present invention as long as the combination does not depart from the spirit of the present application.

Claims (10)

1. The utility model provides a temperature control device of magnetic suspension float valve radiator, its characterized in that, temperature control device (10) include magnetic pole (11), float valve (12) and driving piece (13), float valve (12) interval ground cover is established on magnetic pole (11), float valve (12) have with inboard magnetism part that magnetic pole (11) are adjacent with keep away from the outside magnetism part of magnetic pole (11), inboard magnetism part with magnetic pole (11) produce repellent magnetic force each other, make float valve (12) for magnetic pole (11) suspend, driving piece (13) be the magnetic part and can with outside magnetism part produces the magnetic force of attracting each other.

2. Temperature control device of a magnetic suspension float valve radiator according to claim 1, characterized in that the magnetic rod (11) is arranged to be insertable into the water supply header (20) of the radiator, and the cross section of the float valve (12) is arranged to match the throughflow cross section of the water supply header (20).

3. A temperature control device of a magnetic suspension float valve radiator according to claim 1, characterized in that the float valve (12) comprises an inner magnetic ring (121) forming the inner magnetic part, an outer magnetic ring (122) forming the outer magnetic part and a connection ring (123) connecting the inner magnetic ring (121) and the outer magnetic ring (122), the connection ring (123) being a light piece with a density not larger than water.

4. The temperature control device of a magnetic suspension float valve radiator according to claim 3, characterized in that the float valve (12) is annular with constant axial and radial dimensions, wherein:

the average density of the floating valve (12) is 0.96kg/L-1 kg/L.

5. The temperature control device of the magnetic suspension float valve radiator according to the claim 3, characterized in that the diameter of the magnetic force rod (11) is 8-12mm, the float valve (12) is arranged to be spaced 2-4 mm from the magnetic force rod (11).

6. The temperature control device of a magnetic suspension float valve radiator according to any one of claims 1 to 5, characterized in that the extension thickness of the float valve (12) along the axial direction of the magnetic rod (11) is 18mm-22 mm.

7. A magnetic suspension floating valve radiator, characterized in that, the magnetic suspension floating valve radiator (100) includes the temperature control device (10) of any one of claims 1-6, the water supply union pipe (20) and the end caps (30) located at both ends of the water supply union pipe (20), the magnetic force rod (11) and the floating valve (12) extend into the water supply union pipe (20) from one end of the water supply union pipe (20) and are fixed in the water supply union pipe (20) through the end caps (30), the driving piece (13) is arranged outside the water supply union pipe (20) and can move along the axial direction of the water supply union pipe (20).

8. A magnetically suspended float valve radiator as claimed in claim 7 wherein the radiator (100) is provided with a recess (40) extending in the axial direction of the water supply connection (20), the drive member (13) being slidably disposed within the recess (40).

9. The heat sink of claim 8, wherein the bottom arc of the recess is the outer wall of the water inlet pipe.

10. A magnetically suspended float valve radiator according to any one of claims 7 to 9 wherein the radiator (100) comprises a plurality of radiating pipes (50) in communication with the water supply header (20), the length of the magnetic rod (11) being arranged to allow the float valve (12) to pass through all of the radiating pipes (50).

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