CN221301439U - Multidirectional rotary heating device - Google Patents

Abstract

The utility model relates to a heating device capable of rotating in multiple directions, which comprises a heating main body, wherein the heating main body comprises a heating component arranged in an inner cavity of a shell, the inner cavity of the shell extends to one end to form an opening, and heat is radiated outwards from the opening; a mounting body for connecting the heating body to an external mounting surface; a rotating component is arranged between the heating main body and the mounting main body, and the rotating component can enable the heating main body to conduct autorotation and/or head swing actions. Compared with the prior art, the utility model has the beneficial effects that: 1. the rotary seat is arranged to realize the rotation and the head swing of the heating main body, realize the omnibearing radiation heat of the rotary main body and can meet the heating requirement of consumers; 2. the wire structure is arranged, so that the position of the wire is not affected when the heating main body rotates or swings, and the problem that the wire is unfavorable for connection when the wire is wound is avoided.

Description

Multidirectional rotary heating device

Technical Field

The utility model relates to the technical field of heaters, in particular to a multidirectional rotary heating device.

Background

The warmer is used for warming and can be roughly divided into a gas warming device, an electric heating device, a boiler warming device and an electric wall hanging stove for warming according to different heating mediums and different heating principles.

However, the existing warmer is single in multiple purposes, and most of the warmer can be only supported on the ground to be placed or hung on a wall, so that certain limitations exist in use, and most of the existing warmer cannot adjust angles, so that the use effect is poor.

The utility model discloses a but grant chinese utility model patent of bulletin number CN219103121U discloses rotation angle's trinity room heater, relates to room heater technical field, including main part and screen panel, the main part is connected and constitutes and form the installation cavity with the screen panel, be provided with heating subassembly in the installation cavity, the both sides of main part all are provided with curb plate, side shield, gasket and side reflecting plate, the side reflecting plate is connected with heating subassembly, connecting strip, support and supporting component have been set gradually to the rear side of main part, supporting component includes fastening component, support component, line box face shell, foot dish face shell and foot dish drain pan, fastening component's both ends are connected with support and support component respectively, line box face shell sets up in the bottom of support component and bottom is provided with the line box drain pan, the foot dish face shell sets up at the top of foot dish drain pan and is connected with the bullet medium. The utility model solves the problems that the existing warmer has certain limitation and can not adjust the angle and lift when in use.

However, the warmer can only rotate, but cannot swing, that is, the warmer can only radiate heat in one direction, but cannot radiate in multiple directions.

Disclosure of utility model

In order to solve the problems in the prior art, the utility model provides a heating device capable of rotating in multiple directions.

The technical scheme for solving the technical problems is as follows: comprising the steps of (a) a step of,

The heating main body comprises a heating component arranged in the inner cavity of the shell, the inner cavity of the shell extends to one end to form an opening, and heat is radiated outwards from the opening;

A mounting body for connecting the heating body to an external mounting surface;

a rotating component is arranged between the heating main body and the mounting main body, and the rotating component can enable the heating main body to conduct autorotation and/or head swing actions.

Through adopting above-mentioned technical scheme, rotate the heating main part, can adjust its radiation area, and make its pendulum head, then can adjust its radiation direction to realize the omnidirectional rotation, satisfy consumer's heating demand.

The technical scheme is further provided as follows: the rotary assembly comprises a rotary seat, and two end parts of the rotary seat are respectively connected with the heating main body and the mounting main body;

The two ends of the rotating seat are respectively a rotating end and a swinging end, and can rotate or swing relative to the connected parts.

The technical scheme is further provided as follows: the heating main body or the installation main body can rotate relative to the rotating end under the action of the rotation main body.

The technical scheme is further provided as follows: the self-rotation mechanism comprises a rotating shaft and a rotating sleeve matched with the rotating shaft, and the rotating sleeve rotates on the rotating shaft; the rotating shaft is formed on a limiting plate, the end face of the limiting plate is attached to the rotating sleeve, and a positioning structure is arranged.

The technical scheme is further provided as follows: the positioning structure is a plurality of positioning tables which are circumferentially arranged on the limiting plate and the rotating sleeve, and positioning grooves matched with the positioning tables are formed between two adjacent positioning tables on the same end face.

Through adopting above-mentioned technical scheme, be provided with a plurality of locating stations and a plurality of constant head tank in this embodiment and match, and need all locating stations to deviate from in the constant head tank all simultaneously, just can make limiting plate relative rotation cover rotatory, guaranteed the stability of rotating body in the locked position.

The technical scheme is further provided as follows: still be equipped with the backstop structure between limiting plate with the rotor plate, the backstop structure is including stopping retaining wall and backstop piece, and the backstop piece runs into the backstop wall at the rotation in-process and produces the interference, and heating main part or installation main part can't continue to rotate.

Through adopting above-mentioned technical scheme, restrict the rotation angle to heating main part, avoid heating main part unlimited rotation to lead to the wire to twist reverse the broken wire that too much produced.

The technical scheme is further provided as follows: the self-rotation mechanism further comprises a limiting structure, the limiting structure is a spring and a limiting piece, the inside of the rotating sleeve is hollow and is far away from the opening at one side of the limiting plate, and the limiting piece is positioned in the rotating sleeve;

And the two ends of the spring are respectively propped against the inner walls of the limiting piece and the rotating sleeve, and the rotating sleeve is propped against one side of the limiting plate.

Through adopting above-mentioned technical scheme, set up the spring and push up holding the swivel sleeve, swivel sleeve is locking with limiting plate terminal surface all the time under the unstressed state, ensures that the heating main part can not move by oneself.

The technical scheme is further provided as follows: the swinging end is hinged on the heating main body or the mounting main body through a pin shaft, so that the rotating seat swings around the pin shaft relative to the heating main body or the mounting main body;

The two side surfaces of the swinging end are provided with connecting planes and are in positioning connection with the heating main body or the mounting main body, and the pin shaft penetrates through the two connecting planes.

The technical scheme is further provided as follows: the end face of the swinging head end, which is used for connecting the two connecting planes, is an arc-shaped peripheral face, and a stop rib is convexly arranged on the arc-shaped peripheral face to interfere with the heating main body or the mounting main body.

The technical scheme is further provided as follows: the wire hole is arranged in the middle of the rotating shaft, and the wire on the heating main body penetrates through the wire hole, so that the wire penetrates through the rotating assembly and extends out of the mounting main body.

Through adopting above-mentioned technical scheme, set up the line structure of walking, when the heating main part is carrying out the rotation or when swaing the head, do not influence the position of wire, avoid the wire to produce the problem that is unfavorable for the connection such as wire winding.

Compared with the prior art, the utility model has the beneficial effects that:

1. The rotary seat is arranged to realize the rotation and the head swing of the heating main body, realize the omnibearing radiation heat of the rotary main body and can meet the heating requirement of consumers;

2. The wiring structure is arranged, so that the position of the wire is not influenced when the heating main body rotates or swings, and the problem that the wire is unfavorable for connection such as winding is avoided;

3. The installation main body is arranged, the heating main body can be installed on any installation seat, the installation main body is installed on the supporting seat to form the vertical warmer, and the installation main body can also be arranged into a hanging type, so that the multipurpose of the heating main body is realized.

Drawings

Fig. 1 is a schematic diagram of an explosive structure according to the present utility model.

Fig. 2 is a schematic structural view of the mounting support of the present utility model.

Figure 3 is an isometric cross-sectional view of the swivel assembly attached to the mounting body.

Fig. 4 is a schematic cross-sectional view of the rotating assembly and mounting body.

Fig. 5 is a schematic view of a connection structure of the rotating assembly and the mounting body.

Fig. 6 is a schematic structural view of the limiting plate.

Fig. 7 is a schematic structural view of the rotating sleeve.

Fig. 8 is a schematic view of an exploded construction of the swivel base and mounting assembly.

The drawings are marked: 100. a heating main body;

200. a mounting main body; 210. a connecting lug;

300. a rotating assembly; 310. a limiting plate; 311. a rotating shaft; 320. a rotating sleeve; 330. a spring; 340. a limiting piece; 350. a rotating seat; 312. a flange; 313. a retaining wall; 321. a stop block; 351. a connection plane; 360. a spring plate; 361. clamping ribs; 352. a clamping groove; 353. stop ribs;

400. A support base;

a. Positioning the convex; b. and a positioning groove.

Detailed Description

In order to further describe the technical means and effects adopted by the present utility model for achieving the intended purpose, the following detailed description will refer to the specific implementation, structure, characteristics and effects according to the present utility model with reference to the accompanying drawings and preferred embodiments.

It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It will be understood that, although the terms upper, middle, lower, top, end, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another for ease of understanding and are not used to define any directional or sequential limitation.

As shown in fig. 1-8, the present embodiment discloses a multi-directional rotary heating apparatus, particularly with reference to fig. 1, comprising,

A heating body 100 including a heating element disposed in a housing cavity extending to one end to form an opening, from which heat is radiated outward;

A mounting body 200 for connecting the heating body 100 to an external mounting surface;

A rotating unit 300 is provided between the heating body 100 and the mounting body 200, and the rotating unit 300 can rotate and/or swing the heating body 100.

The above is the basic scheme of the present embodiment. The two ends of the rotation assembly 300 are respectively connected to the heating body 100 and the mounting body 200, thereby achieving different movable states of the relative connection position of the heating body 100, i.e., rotation and swing.

In this embodiment, the heating body 100 is connected to a rotating side of the rotating assembly 300, and can rotate relative to the rotating assembly 300; the installation body 200 is connected to a swing side of the rotating assembly 300, and the rotating assembly 300 can swing with respect to the installation body 200 with the heating body 100.

In this embodiment, the heating main body 100 is a long-strip-shaped heater, and the radiation area of the heating main body 100 can be adjusted by rotating the heating main body 100, so that the radiation direction of the heating main body can be adjusted by swinging the heating main body, thereby realizing omnibearing rotation and meeting the heating requirement of consumers.

The structure of the heating main body 100 in this embodiment is consistent with that of the warmer in the prior art, the heating component is electrified to generate heat, the heat is radiated outwards from the opening after passing through the reflecting plate in the inner cavity, and the anti-scalding net is arranged at the opening.

Meanwhile, the installation body 200 is provided in this embodiment, so that the heating body 100 can be installed on any installation seat, for example, on the support seat 400 to form a vertical warmer, and as shown in fig. 2, the installation body can also be provided as a suspension type, so as to realize multiple purposes of the heating body 100.

The specific implementation of the rotating assembly 300 in this embodiment is: the rotating assembly 300 includes a rotating base 350, and two ends of the rotating base 350 are respectively connected to the heating body 100 and the mounting body 200;

The two ends of the rotating base 350 are a rotating end and a swinging end, respectively, and can rotate or swing relative to the connected components.

In this embodiment, the heating body 100 is connected to the rotating end, and can rotate relative to the rotating end; the mounting body 200 is connected to the swing end, so that the swivel base 350 swings the heating body 100 relative to the mounting member.

In this embodiment, the swing head is arranged.

Specifically, the rotating end is a housing that is hollow and extends to the end face to form an opening, and a rotation mechanism is disposed in the housing, and the heating main body 100 or the mounting main body 200 can rotate relative to the rotating end under the action of the rotation main body.

The cross section of the rotating end in the embodiment is circular, and the autorotation mechanism is positioned in the inner cavity of the rotating end and rotates in the inner cavity.

The specific implementation manner of the rotation mechanism in this embodiment is as follows: the rotation mechanism comprises a rotating shaft 311 and a rotating sleeve 320 matched with the rotating shaft 311, and the rotating sleeve 320 rotates on the rotating shaft 311; the rotating shaft 311 is formed on a limiting plate 310, and the end surface of the limiting plate 310 is attached to the rotating sleeve 320, and a positioning structure is provided.

In order to ensure the stability of the heating assembly during the rotation, the limiting plate 310 is fixed to the back of the heating body 100 and is closely attached to the back of the heating body 100; the rotating sleeve 320 is embedded into the rotating end of the rotating seat 350, and the end surface of the rotating sleeve 320 is tightly positioned with the limiting plate 310, meanwhile, in the arrangement of the embodiment, the end surface of the rotating sleeve 320 is exposed to the outside of the rotating end, the limiting plate 310 is provided with the flange 312, the flange 312 is tightly adhered with the edge of the rotating end, and the rotating end is sealed.

The specific implementation manner of the positioning structure in this embodiment is as follows: the positioning structure is a plurality of positioning tables circumferentially arranged on the limiting plate 310 and the rotating sleeve 320, and a positioning groove b matched with the positioning table is formed between two adjacent positioning tables on the same end face.

The limiting plate 310 and the rotating sleeve 320 are provided with positioning tables which are circumferentially distributed. The positioning groove b on the limiting plate 310 is matched with the positioning table on the rotating sleeve 320, and meanwhile, the positioning groove b on the rotating sleeve 320 is matched with the positioning table on the limiting plate 310, so that a stable positioning structure is formed.

When the rotating body rotates, the positioning table is separated from the positioning groove b, so that the limiting plate 310 rotates relative to the rotating sleeve 320, and when the rotating body rotates to a proper position, the positioning table is clamped into the positioning groove b at the corresponding position, and locking between the limiting plate 310 and the rotating sleeve 320 is realized.

Compared with the arrangement of a single positioning structure, the positioning tables are matched with the positioning grooves b, and all positioning tables are required to be simultaneously separated from the positioning grooves b, so that the limiting plate 310 can rotate relative to the rotating sleeve 320, and the stability of the rotating main body in the locking position is ensured.

In this structure, the positioning tables on the rotating sleeve 320 and the limiting plate 310 may be set to have the same size and shape, and the profiles of the positioning grooves b on the rotating sleeve 320 and the limiting plate 310 are also the same; it is also possible to provide the positioning table on the rotation sleeve 320 and the limiting plate 310 with different size and shape, but the positioning table and the corresponding positioning groove b must be matched in shape.

Specifically, in this embodiment, in order to make the heating main body 100 rotate conveniently, two side walls of the positioning table along the rotation direction are set to be inclined planes, that is, two groove walls of the positioning groove b between two positioning tables are set to be inclined planes, when the heating main body 100 needs to rotate, the positioning table slides out along the inclined planes, and a user applies a smaller force to rotate the heating main body 100.

In the locked state, the positioning table is tightly attached to the bottom of the positioning groove b, and when the positioning table rotates, the table top of the positioning table is required to be separated from the bottom of the groove, namely, the end surface of the limiting plate 310 is required to be separated from the end surface of the rotating sleeve 320 by a certain distance, so that the rotation can be realized; in order to enable the limiting plate 310 to automatically reset after rotating, in this embodiment, the rotation mechanism further includes a limiting structure, the limiting structure is a spring 330 and a limiting plate 340, the inside of the rotating sleeve 320 is hollow and is open at one side far away from the limiting plate 310, and the limiting plate 340 is located in the rotating sleeve 320;

The two ends of the spring 330 are respectively supported on the limiting plate 340 and the inner wall of the rotating sleeve 320, so as to support the rotating sleeve 320 towards one side of the limiting plate 310.

Specifically, in this embodiment, the limiting plate 340 is located in the rotating seat 350, the spring 330 is propped between the inner wall of the rotating sleeve 320 and the limiting plate 340, when the user rotates the heating assembly, the limiting plate 310 also rotates, during the rotation process, the inclined side wall of the positioning table on the limiting plate 310 generates a thrust force in an inclined direction to the side wall of the positioning table on the rotating sleeve 320, and the component force of the thrust force in the axial direction pushes the rotating sleeve 320 to the inside of the rotating seat 350, so that the rotating sleeve 320 moves to a side far away from the limiting plate 310, and the positioning table is separated from the positioning groove b;

When the positioning table on the limiting plate 310 rotates to the next positioning groove b, the spring 330 ejects the rotary sleeve 320, so that the positioning table is matched with the positioning groove b, and the limiting plate 310 and the rotary sleeve 320 are tightly stuck and locked, thereby realizing self-locking.

In this embodiment, the rotating base 350 is provided with a through hole for routing, and the diameter of the through hole is smaller than the diameter of the limiting piece 340, so that the limiting piece 340 is always attached to the cavity wall of the inner cavity of the rotating end on the rotating base 350.

When the heating main body 100 rotates, the wire arranged in the heating main body 100 also rotates, so as to avoid wire breakage caused by excessive wire torsion due to unlimited rotation of the heating main body 100, in this embodiment, the rotation angle of the heating main body 100 is limited, and the specific embodiment is as follows: a stop structure is further disposed between the limiting plate 310 and the rotating sleeve 320, the stop structure includes a stop wall 313 and a stop block 321, and the stop block 321 encounters the stop wall 313 to interfere with the rotation process, so that the heating main body 100 or the mounting main body 200 cannot continue to rotate.

In this embodiment, the stop walls 313 are disposed on the limiting plate 310, the stop blocks 321 are disposed on the rotating sleeve 320 and are both disposed on the outer side of the positioning structure, and the stop walls 313 and the stop blocks 321 are both disposed with two and are matched in a staggered manner, i.e., each stop block 321 is disposed between two stop walls 313, and each stop wall 313 is also disposed between two stop blocks 321.

In this embodiment, the swing structure of the heating main body 100 is consistent with the swing mode in the prior art, and the specific implementation manner is as follows: the swinging end is hinged on the heating main body 100 or the installation main body 200 through a pin shaft, so that the rotating seat 350 swings around the pin shaft relative to the heating main body 100 or the installation main body 200;

The two side surfaces of the swinging end are provided with connecting planes 351 and are in positioning connection with the heating main body 100 or the mounting main body 200, and the pin shaft penetrates through the two connecting planes 351.

Specifically, two connecting lugs 210 are arranged on the mounting main body 200, the swinging end is clamped between the two connecting lugs 210, and the pin shaft sequentially passes through the connecting lugs 210 and the swinging end;

Meanwhile, the elastic sheet 360 is inserted on the inner wall of the two connecting lugs 210, the elastic sheet 360 is provided with the clamping rib 361, the clamping rib 361 penetrates through the diameter setting of the pin shaft, the two connecting planes 351 of the swinging head end are provided with a plurality of clamping grooves 352 which can be matched with the clamping rib 361, when the rotating seat 350 rotates relative to the mounting main body 200, the clamping grooves 352 rotate to positions corresponding to the clamping ribs 361, and the clamping ribs 361 are clamped into the clamping grooves 352, so that the rotating seat 350 and the mounting main body 200 are positioned, and at the moment, the rotating seat 350 cannot swing relative to the mounting main body 200 under the condition of not being affected by external force.

In this embodiment, the swing angle of the heating body 100 is also limited, and the specific embodiment thereof is as follows: the end surface of the swinging end, which is used for connecting the two connecting planes 351, is an arc-shaped peripheral surface, and a stop rib 353 is convexly arranged on the arc-shaped peripheral surface to interfere with the heating main body 100 or the installation main body 200.

The two stop ribs 353 are arranged, when the heating main body 100 swings upwards to the limit position, the stop ribs 353 interfere with the mounting main body 200, and the heating main body 100 cannot continue to swing upwards; similarly, when the heating body 100 swings downward to the limit position, the lower stopper rib 353 interferes with the mounting body 200, and the heating body 100 cannot continue to swing downward.

The embodiment also sets up the line structure in revolution mechanic, when heating main part 100 is rotating or swaying, does not influence the position of wire, avoids the wire to produce the problem that is unfavorable for the connection such as wire winding, and its concrete implementation is: the middle of the rotating shaft 311 is provided with a wiring hole, and the wires on the heating body 100 pass through the wiring hole, so as to extend out of the mounting body 200 through the rotating assembly 300.

The present utility model is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present utility model.

Claims (9)

1. A heating device capable of rotating in multiple directions comprises,

A heating main body (100) comprising a heating component arranged in an inner cavity of the shell, wherein the inner cavity of the shell extends to one end to form an opening, and heat is radiated outwards from the opening;

A mounting body (200) for connecting the heating body (100) to an external mounting surface;

The method is characterized in that: a rotating assembly (300) is arranged between the heating main body (100) and the mounting main body (200), and the rotating assembly (300) can enable the heating main body (100) to perform autorotation and/or head swing actions;

The rotary assembly (300) comprises a rotary seat (350), and two ends of the rotary seat (350) are respectively connected with the heating main body (100) and the mounting main body (200);

The two ends of the rotating seat (350) are respectively a rotating end and a swinging end, and can rotate or swing relative to the connected parts.

2. A multi-directional rotary heating apparatus as set forth in claim 1 wherein: the heating main body (100) or the installation main body (200) can rotate relative to the rotating end under the action of the rotating main body.

3. A multi-directional rotary heating apparatus as set forth in claim 2 wherein: the autorotation assembly comprises a rotating shaft (311) and a rotating sleeve (320) matched with the rotating shaft (311), and the rotating sleeve (320) rotates on the rotating shaft (311); the rotating shaft (311) is formed on a limiting plate (310), the end face of the limiting plate (310) is attached to the rotating sleeve (320), and a positioning structure is arranged.

4. A multi-directional rotary heating apparatus as set forth in claim 3 wherein: the positioning structure is a plurality of positioning tables which are circumferentially arranged on the limiting plate (310) and the rotating sleeve (320), and positioning grooves (b) matched with the positioning tables are formed between two adjacent positioning tables on the same end face.

5. The multi-directional rotating heating apparatus of claim 4, wherein: still be equipped with the backstop structure between limiting plate (310) with swivel sleeve (320), the backstop structure includes stopping wall (313) and backstop piece (321), and backstop piece (321) meet stopping wall (313) and produce the interference at the rotation in-process, and heating main part (100) or installation main part (200) can't continue to rotate.

6. A multi-directional rotary heating apparatus as set forth in claim 3 wherein: the self-rotation assembly further comprises a limiting structure, the limiting structure comprises a spring (330) and a limiting piece (340), the inside of the rotary sleeve (320) is hollow, one side, far away from the limiting plate (310), of the limiting piece (340) is located in the rotary sleeve (320);

The two ends of the spring (330) are respectively propped against the inner walls of the limiting piece (340) and the rotating sleeve (320), and the rotating sleeve (320) is propped against one side of the limiting plate (310).

7. A multi-directional rotary heating apparatus as set forth in claim 1 wherein: the swinging end is hinged on the heating main body (100) or the mounting main body (200) through a pin shaft, so that the rotating seat (350) swings around the pin shaft relative to the heating main body (100) or the mounting main body (200);

The two side surfaces of the swinging end are provided with connecting planes (351) and are in positioning connection with the heating main body (100) or the mounting main body (200), and the pin shaft penetrates through the two connecting planes (351).

8. The multi-directional rotating heating apparatus of claim 7, wherein: the end face of the swinging head end, which is used for connecting the two connecting planes (351), is an arc-shaped peripheral face, and a stop rib (353) is convexly arranged on the arc-shaped peripheral face to interfere with the heating main body (100) or the mounting main body (200).

9. A multi-directional rotary heating apparatus as set forth in claim 3 wherein: and a wiring hole is formed in the middle of the rotating shaft (311), and a wire on the heating main body (100) passes through the wiring hole so as to penetrate through the rotating assembly (300) and extend out to the mounting main body (200).