CN114811941A

CN114811941A - Horizontal full-submerged electrode boiler with linear bearing

Info

Publication number: CN114811941A
Application number: CN202210377914.4A
Authority: CN
Inventors: 李春明; 戴叶青; 陈怡超; 徐孝明; 叶柱辉
Original assignee: Zhejiang Shangneng Boiler Co ltd
Current assignee: Zhejiang Shangneng Boiler Co ltd
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2022-07-29
Anticipated expiration: 2040-12-22
Also published as: CN114704957B; CN114704957A; CN112628702B; CN114811941B; CN112628702A

Abstract

The application discloses take linear bearing's horizontal full submerged electrode boiler, including furnace body, looks electrode, zero-bit electrode, isolation shield, lead screw and mounting panel, looks electrode all is fixed in with zero-bit electrode in the furnace body, the looks electrode is located in the zero-bit electrode, mounting panel slidable mounting is in the furnace body, the isolation shield is fixed on the mounting panel, the lead screw rotates sealed installation on the furnace body, the mounting panel is in the same place with the lead screw cooperation, the isolation shield is located between looks electrode and the zero-bit electrode, still includes adjusting screw, sleeve, adjusting nut, the sleeve is fixed on the mounting panel. The invention has the following beneficial effects: through increasing sleeve, adjusting screw and adjusting nut for the mounting panel between for the contained angle can be adjusted between the lead screw, make keep parallel all the time between isolation shield, looks electrode, the zero position electrode three.

Description

Horizontal full-submerged electrode boiler with linear bearing

The application is a divisional application with the application date of 2020, 12 months and 12 days, the application number of 2020115279164 and the name of the invention being 'horizontal full submerged electrode boiler'.

Technical Field

The invention relates to the field of boiler equipment, in particular to a horizontal full-submerged electrode boiler with a linear bearing.

Background

The electrode boilers have strong adaptability and larger use amount due to convenient use, but the existing boilers are all vertical boilers, such as the electrode boilers shown in patent CN110375286A (or patent CN207945820U and patent CN207945820U) (i.e. the isolation shield is vertical to the ground when being adjusted and moved), the height of the vertical boiler is relatively high, so that the installation place has a limit on the clear height when the vertical boiler is installed, and many buildings are designed for a long time, and the height of the vertical boiler is even lower than the height of the boiler, so that in order to install the boiler in the buildings, the vertical boiler is installed by adopting a horizontal method (i.e. the boiler body is horizontal, the phase electrode, the zero electrode, the isolation shield and the tie rod lifting mechanism are all horizontally installed, and the isolation shield moves left and right along the electrode horizontal direction when the boiler is moved), but the installation by adopting the horizontal method brings a problem, namely, due to the self gravity action and the impact action of water flow, the isolation shield, the phase electrode and the zero position electrode which are originally in a concentric state can deviate and become non-concentric (namely, the isolation shield, the phase electrode and the zero position electrode become non-parallel), and once the isolation shield, the phase electrode and the zero position electrode become non-concentric, the isolation shield cannot be consistent when the current is adjusted, so that the tripping phenomenon is caused.

Because the phase electrode and the zero position electrode in the boiler are kept fixed relative to the boiler body of the boiler, the stability of the phase electrode (or the zero position electrode) can be improved by adding a fixing piece between the phase electrode (or the zero position electrode) and the boiler body, and the phase electrode and the zero position electrode are always in a concentric state.

Disclosure of Invention

Aiming at the problems, the invention provides a horizontal full-submerged electrode boiler with a linear bearing.

The technical scheme adopted by the invention is as follows:

a horizontal full-submerged electrode boiler with a linear bearing comprises a boiler body, a phase electrode, a zero-position electrode, an isolation shield, a lead screw and a mounting plate, wherein the phase electrode and the zero-position electrode are fixed in the boiler body, the phase electrode is positioned in the zero-position electrode, the mounting plate is slidably mounted in the boiler body, the isolation shield is fixed on the mounting plate, the lead screw is rotatably and hermetically mounted on the boiler body, the mounting plate and the lead screw are matched together, the isolation shield is positioned between the phase electrode and the zero-position electrode, the horizontal full-submerged electrode boiler further comprises an adjusting screw, a sleeve and an adjusting nut, the sleeve is fixed on the mounting plate and sleeved on the lead screw, the adjusting nut is mounted at two ends of the adjusting screw, the sleeve and the mounting plate are fixed together with the adjusting nut through connecting steel wires respectively, and the adjusting screw is not parallel to the lead screw, the two ends of the screw rod are in sealed and rotating fit with the furnace body.

In the electrode boiler of above-mentioned structure, through increasing the sleeve, adjusting screw and adjusting nut, the mounting panel of making can be adjusted for the contained angle between the lead screw, because the isolation shield is installed on the mounting panel, so after the contained angle between mounting panel and the lead screw takes place to adjust, the position between isolation shield and the lead screw also can be adjusted, and phase electrode and zero position electrode are in fixed state for the lead screw all the time, so the boiler of above-mentioned structure can adjust the position between isolation shield for the phase electrode at any time, make keep parallel all the time between isolation shield, phase electrode, the zero position electrode three.

The concrete connection steel wire one end is in the same place with adjusting nut welding, and the connection steel wire other end is in the same place with mounting panel (or sleeve) welded fastening, and when perhaps being provided with the hitch on mounting panel (or sleeve), the connection steel wire can direct winding fix on the hitch. The two ends of the lead screw are in sealed rotary fit with the furnace body through a sealing bearing.

Optionally, the phase electrode is cylindrical, the zero electrode is cylindrical, and the isolation shield is cylindrical; the central axes of the phase electrode, the zero-position electrode and the isolation shield are coincident.

The central axes of the three parts coincide with each other, so that the three parts are concentric, the current intensity is convenient to regulate and control, and the mounting and the use are convenient.

Optionally, the screw driver further comprises a linear bearing, and the linear bearing is arranged between the screw rod and the sleeve.

The linear bearing is arranged to enable the sleeve to be more stable when sliding on the screw rod, meanwhile, the stability of the sleeve is improved, the sleeve is guaranteed not to shake, and meanwhile the screw rod is well protected.

Optionally, the mounting plate further comprises a center nut, the center nut is fixed at the center of the mounting plate pair, and the mounting plate is matched with the screw rod through the center nut.

The central nut is arranged at the center of the mounting plate, the screw rod is matched with the mounting plate together, so that when the mounting plate inclines relative to the screw rod, the mounting plate can still smoothly move along the screw rod due to the fact that the central nut is matched with the screw rod, the extrusion force of the screw rod can be reduced when the angle of the mounting plate is adjusted, and the service life of the screw rod is longer.

Optionally, a guide rail is arranged on the inner wall of the furnace body, a sliding groove is arranged on the mounting plate, and the mounting plate is in sliding fit with the guide rail through the sliding groove of the mounting plate.

The guide rail and the sliding groove have the function of limiting the sliding of the mounting plate, so that the mounting plate can move along the screw rod when the screw rod rotates; secondly, in order to increase the stability of mounting panel for the mounting panel is difficult for taking place the skew for the lead screw more.

Optionally, the phase electrode is installed in the furnace body through a ceramic rod, the ceramic rods are fixed at both ends of the phase electrode, the ceramic rods of the phase electrode are on a straight line, and the ceramic rods are parallel to the lead screw.

The ceramic rod at one end of the phase electrode is a hollow ceramic rod (several circles of stainless steel pipes can be sleeved outside the ceramic pipe when necessary for ensuring the strength) for laying the electric wire, and the other end of the ceramic rod is a solid ceramic rod.

Optionally, the mounting panel perpendicular to the lead screw, the isolation shield vertical fixation is in on the mounting panel, the isolation shield is on a parallel with the lead screw.

Optionally, the isolation shield has three, adjusting screw has three, the isolation shield is in the equal radian ground of equidistance distributes on the mounting panel, adjusting screw centers on the equal radian's of lead screw distribution of equidistance.

The three isolation shields are used for matching three pairs of phase electrodes and zero position electrodes, the three adjusting screws are used for simplifying the installation procedure, and the round surface of the installation plate is divided into three by the three adjusting screws. The zero-position electrode is fixed on the furnace body through a fixed steel plate. The three adjusting screws are in a suspended state, so that the adjusting sensitivity of the mounting plate can be improved.

Optionally, the furnace body is provided with a circulation inlet and a circulation outlet, and the circulation inlet and the circulation outlet are both communicated with the space in the furnace body; the furnace body is provided with a water replenishing port and an outlet, and the water replenishing port and the outlet are communicated with the space in the furnace body.

The circulation inlet and the circulation outlet are used for realizing water circulation in the furnace body, the water replenishing port is used for replenishing water in the furnace body, and the outlet is a channel for steam or hot water to leave the furnace body. When hot water is generated, the boiler is a horizontal full-submerged electrode hot water boiler, and when steam is generated, the boiler is a horizontal full-submerged electrode steam boiler.

Optionally, a through hole is formed in the mounting plate, a ceramic rod for mounting the phase electrode penetrates through the through hole, and the diameter of the ceramic rod is smaller than that of the through hole.

The diameter that the through-hole on the mounting panel is greater than the ceramic rod is in order to guarantee that when the mounting panel takes place to deflect, the mounting panel can not cause the extrusion to the ceramic rod, ensures that the ceramic rod can not be cracked, ensures simultaneously that rivers can pass through smoothly between ceramic rod and the mounting panel for the impact strength of rivers in the furnace body to looks electrode, zero-position electrode and isolation shield weakens by a wide margin, makes isolation shield, looks electrode and zero-position electrode more stable, and difficult emergence is turned round partially.

The invention has the beneficial effects that: through increasing sleeve, adjusting screw and adjusting nut for the mounting panel between for the contained angle can be adjusted between the lead screw, make keep parallel all the time between isolation shield, looks electrode, the zero position electrode three.

Description of the drawings:

figure 1 is a schematic sketch of a horizontal full submerged electrode boiler with linear bearings,

figure 2 is a schematic cross-sectional view taken along line a-a of figure 1,

fig. 3 is a schematic sectional view taken along the direction B-B in fig. 1.

The figures are numbered: 1. the device comprises a furnace body, 101, a circulation outlet, 102, a circulation inlet, 103, a water replenishing port, 104, an outlet, 2, a guide rail, 3, a mounting plate, 301, a sliding groove, 302, a through hole, 4, a fixed steel plate, 5, a zero position electrode, 6, a phase electrode, 7, an isolation shield, 8, a ceramic rod, 9, a lead screw, 10, a connecting steel wire, 11, an adjusting nut, 12, an adjusting screw, 13, a central nut, 14, a sleeve, 15, a linear bearing, 16, a support, 17, a partition plate, 1701 and a jet orifice.

The specific implementation mode is as follows:

the present invention will now be described in detail with reference to the drawings.

As shown in attached

drawings

1, 2 and 3, the horizontal full-submerged electrode boiler with the linear bearing comprises a boiler body 1, a phase electrode 6, a zero-position electrode 5, an isolation shield 7, a screw rod 9 and a mounting plate 3, wherein the phase electrode 6 and the zero-position electrode 5 are fixed in the boiler body 1, the phase electrode 6 is positioned in the zero-position electrode 5, the mounting plate 3 is slidably mounted in the boiler body 1, the isolation shield 7 is fixed on the mounting plate 3, the screw rod 9 is rotatably and hermetically mounted on the boiler body 1, the mounting plate 3 is matched with the screw rod 9, the isolation shield 7 is positioned between the phase electrode 6 and the zero-position electrode 5, the horizontal full-submerged electrode boiler also comprises an adjusting screw rod 12, a sleeve and an adjusting nut 11, the sleeve is fixed on the mounting plate 3 and sleeved on the screw rod 9, the adjusting nut 11 is mounted at two ends of the adjusting screw rod 12, the sleeve and the mounting plate 3 are respectively fixed with the adjusting nut 11 through a connecting steel wire 10, the adjusting screw 12 is not parallel to the screw rod 9, and two ends of the screw rod 9 are in sealed rotary fit with the furnace body 1.

In the electrode boiler with the structure, the sleeve, the adjusting screw 12 and the adjusting nut 11 are added, so that the included angle between the mounting plate 3 and the lead screw 9 can be adjusted, the isolation shield 7 is mounted on the mounting plate 3, after the included angle between the mounting plate 3 and the lead screw 9 is adjusted, the position between the isolation shield 7 and the lead screw 9 can also be adjusted, and the phase electrode 6 and the zero-position electrode 5 are always in a fixed state relative to the lead screw 9, so that the position between the isolation shield 7 and the phase electrode 6 can be adjusted at any time, and the isolation shield 7, the phase electrode 6 and the zero-position electrode 5 are always kept parallel.

Specifically, one end of the connecting steel wire 10 is welded with the adjusting nut 11, the other end of the connecting steel wire 10 is welded and fixed with the mounting plate 3 (or the sleeve), or when the mounting plate 3 (or the sleeve) is provided with the sleeve hook, the connecting steel wire 10 can be directly wound and fixed on the sleeve hook. Two ends of the screw rod 9 are in sealed rotary fit with the furnace body 1 through a sealing bearing.

As shown in fig. 1, 2 and 3, the phase electrode 6 is cylindrical, the null electrode 5 is cylindrical, and the isolation shield 7 is cylindrical; the central axes of the phase electrode 6, the zero electrode 5 and the isolation shield 7 are coincident.

As shown in fig. 1, fig. 2 and fig. 3, the screw driver further includes a linear bearing 15, and the linear bearing 15 is disposed between the screw 9 and the sleeve.

The linear bearing 15 is arranged to stabilize the sleeve 14 when sliding on the screw 9, and also to improve the stability of the sleeve 14 itself, so as to ensure that the sleeve 14 itself does not shake and to protect the screw 9 well.

As shown in fig. 1, fig. 2 and fig. 3, the screw driver further includes a center nut 13, the center nut 13 is fixed at the center of the pair of mounting plates 3, and the mounting plates 3 are matched with the screw rod 9 through the center nut 13.

The central nut 13 is arranged at the center of the mounting plate 3, the screw 9 is matched with the mounting plate 3, so that when the mounting plate 3 inclines relative to the screw 9, the mounting plate 3 can still smoothly move along the screw 9 due to the matching of the central nut 13 and the screw 9, and the existence of the central nut 13 can reduce the extrusion force of the screw 9 when the angle of the mounting plate 3 is adjusted, so that the service life of the screw 9 is longer.

As shown in fig. 1, fig. 2 and fig. 3, a guide rail 2 is arranged on the inner wall of the furnace body 1, a chute 301 is arranged on the mounting plate 3, and the mounting plate 3 is in sliding fit with the guide rail 2 through the chute 301.

The guide rail 2 and the sliding groove 301 have the function of limiting the sliding of the mounting plate 3, so that the mounting plate 3 can move along the screw 9 when the screw 9 rotates; secondly, in order to increase the stability of the mounting plate 3, the mounting plate 3 is more difficult to generate the offset relative to the screw rod 9.

As shown in the attached

drawings

1, 2 and 3, the phase electrode structure further comprises a ceramic rod 8, the phase electrode 6 is installed in the furnace body 1 through the ceramic rod 8, the ceramic rods 8 are fixed at two ends of the phase electrode 6, the ceramic rods 8 of the phase electrode 6 are on a straight line, and the ceramic rods 8 are parallel to the lead screw 9.

The ceramic rod 8 can be solid or hollow, or solid and hollow combined, in the scheme, the ceramic rod 8 is mounted at both ends of the phase electrode 6, and the phase electrode 6 needs to be powered by an electric wire, so that the ceramic rod 8 at one end of the phase electrode 6 is the hollow ceramic rod 8 (several circles of stainless steel pipes can be sleeved outside the ceramic rod when necessary to ensure the strength) for laying the electric wire, the solid ceramic rod 8 is adopted at the other end, and the ceramic rod and the furnace body are directly sealed by a sealing ring.

As shown in fig. 1, fig. 2 and fig. 3, the mounting plate 3 is perpendicular to the lead screw 9, the isolation shield 7 is vertically fixed on the mounting plate 3, and the isolation shield 7 is parallel to the lead screw 9.

As shown in fig. 1, 2 and 3, there are three isolation shields 7, three adjusting screws 12, the isolation shields 7 are equidistantly distributed on the mounting plate 3 in an equal arc manner, and the adjusting screws 12 are equidistantly distributed around the screw rod 9 in an equal arc manner.

The three isolation shields 7 are used for matching the three pairs of phase electrodes 6 and the zero position electrode 5, the three adjusting screws 12 are used for simplifying the installation procedure, and the circular surface of the installation plate 3 is divided into three by the three adjusting screws 12. The zero electrode 5 is fixed on the furnace body 1 through a fixed steel plate 4.

As shown in the attached

drawings

1, 2 and 3, the furnace body 1 is provided with a circulating inlet 102 and a circulating outlet 101, and the circulating inlet 102 and the circulating outlet 101 are both communicated with the space in the furnace body 1; the furnace body 1 is provided with a water replenishing port 103 and an exit port 104, and the water replenishing port 103 and the exit port 104 are both communicated with the space in the furnace body 1.

The circulation inlet 102 and the circulation outlet 101 realize the water circulation in the furnace body 1, the water replenishing port 103 is used for replenishing water in the furnace body 1, and the outlet 104 is a channel for steam or hot water to leave the furnace body 1. When hot water is generated, the boiler is a horizontal full-submerged electrode hot water boiler, and when steam is generated, the boiler is a horizontal full-submerged electrode steam boiler.

As shown in fig. 1, fig. 2 and fig. 3, the mounting plate 3 is provided with a through hole 302, the ceramic rod 8 for mounting the phase electrode 6 passes through the through hole 302, and the diameter of the ceramic rod 8 is smaller than that of the through hole 302.

The diameter that the through-hole 302 on the mounting panel 3 is greater than ceramic rod 8 is in order to guarantee that when mounting panel 3 takes place to deflect, mounting panel 3 can not cause the extrusion to ceramic rod 8, it can not be cracked to guarantee ceramic rod 8, guarantee simultaneously that rivers can pass through smoothly between ceramic rod 8 and the mounting panel 3, make rivers in the furnace body 1 weaken to a wide margin to the impact strength of looks electrode 6, zero position electrode 5 and isolation shield 7, make isolation shield 7, looks electrode 6 and zero position electrode 5 more stable, difficult emergence is turned round partially.

A partition 17 is provided in the furnace body 1, and a jet orifice 1701 is provided in the partition 17. The outer wall of the furnace body 1 is provided with a support 16.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, which is defined by the claims and their equivalents, and can be directly or indirectly applied to other related fields of technology.

Claims

1. A horizontal full-submerged electrode boiler with a linear bearing comprises a boiler body, a phase electrode, a zero position electrode, an isolation shield, a lead screw and a mounting plate, the phase electrode and the zero position electrode are both fixed in the furnace body, the phase electrode is positioned in the zero position electrode, the mounting plate is slidably mounted in the furnace body, the isolation shield is fixed on the mounting plate, the screw rod is rotatably and hermetically mounted on the furnace body, the mounting plate is matched with the screw rod, the isolation shield is positioned between the phase electrode and the zero position electrode, it is characterized by also comprising an adjusting screw rod, a sleeve and an adjusting nut, wherein the sleeve is fixed on the mounting plate, the sleeve is sleeved on the screw rod, the adjusting nuts are arranged at the two ends of the adjusting screw rod, the sleeve and the mounting plate are fixed together with an adjusting nut through connecting steel wires respectively, and the adjusting screw rod is not parallel to the screw rod;

the bearing is arranged between the screw rod and the sleeve;

the phase electrode is arranged in the furnace body through the ceramic rod, the ceramic rods are fixed at two ends of the phase electrode, the ceramic rods of the phase electrode are on the same straight line, and the ceramic rods are parallel to the lead screw;

the mounting plate is provided with a through hole, a ceramic rod for mounting the phase electrode penetrates through the through hole, and the diameter of the ceramic rod is larger than that of the through hole.

2. The horizontal full submerged electrode boiler with linear bearing according to claim 1, wherein the phase electrode is cylindrical, the zero electrode is cylindrical, and the isolation shield is cylindrical; the central axes of the phase electrode, the zero-position electrode and the isolation shield are coincident.

3. The horizontal full submerged electrode boiler with the linear bearing according to claim 1, further comprising a center nut fixed at the center of the pair of mounting plates, the mounting plates being engaged with a lead screw through the center nut.

4. The horizontal full-submerged electrode boiler with the linear bearing according to claim 1, wherein the inner wall of the boiler body is provided with a guide rail, the mounting plate is provided with a sliding groove, and the mounting plate is in sliding fit with the guide rail through the sliding groove.

5. The horizontal full submerged electrode boiler with linear bearings according to claim 1, wherein the mounting plate is perpendicular to the lead screw, the isolation shield is vertically fixed on the mounting plate, and the isolation shield is parallel to the lead screw.

6. The horizontal full submerged electrode boiler with linear bearings according to claim 1, wherein there are three said isolation shields and three said adjusting screws, said isolation shields being equally spaced in equal arc on said mounting plate, said adjusting screws being equally spaced in equal arc around said screw.

7. The horizontal full-submerged electrode boiler with the linear bearing according to claim 1, wherein the boiler body is provided with a circulating inlet and a circulating outlet, and the circulating inlet and the circulating outlet are both communicated with the space in the boiler body; the furnace body is provided with a water replenishing port and an outlet, and the water replenishing port and the outlet are communicated with the space in the furnace body.