KR200496554Y1 - Removable heat sink electric stove - Google Patents

Abstract

The present invention discloses a movable heat radiation pipe electric heater, and includes a heat radiation pipe (1), a reflector (2) installed toward the heat radiation pipe (1), and a moving mechanism. The heat radiation pipe 1 is located at the focal point of the reflector 2, the heat radiation pipe 1 is connected to the moving mechanism, and can move under the linkage of the moving mechanism. Since the heat radiation tube can move under the linkage of the moving mechanism, different heat dissipation can be obtained under the premise that the output does not change when moved to a different position. When moving forward relative to the reflector focal length position, the column can be focused in front. Conversely, heat can be dissipated relatively uniformly when moving backward, and the user can select the position of the heat sink as needed. The present invention has advantages such as simple operation, high thermal efficiency, and economical energy saving.

Description

Removable heat pipe electric stove {REMOVABLE HEAT SINK ELECTRIC STOVE}

The present invention relates to the field of household electric heaters, and specifically relates to movable heat-radiating tube electric heaters.

When the heating element in an electric stove is a radial heating element such as a carbon tube, a quartz tube, a halogen tube, or a black tube, a reflector is usually installed. A reflector is usually a parabolic surface (equation Y²=2PX, Z=0). This parabolic curve allows the reflector to reflect and emit heat in a parallel fashion when the heat sink is placed at the parabolic focal length. Conversely, if they are not at the focal length, they reflect heat in a converging or dissipating way.

The technical problem to be solved by the present invention is to provide a new type of movable heat radiation tube electric heater that allows users to feel a better sense of experience.

In order to solve the above technical problem, the technical solution provided by the present invention is as follows.
The movable heat radiation pipe electric heater of the present invention includes a rod-shaped heat radiation pipe (1) disposed long in the vertical direction; a reflector (2) disposed at the rear of the heat radiation pipe (1) and formed long in the vertical direction while forming a curved shape with both sides curved forward; A movement mechanism for moving the heat radiation pipe 1 in the forward and backward directions with respect to the reflector 2; the movement mechanism includes a rotation control mechanism 3 used for rotational movement; Rotation-parallel movement that connects the rotation control mechanism 3 and the heat radiation tube 1 and moves the heat radiation tube 1 forward and backward while converting the rotational motion of the rotation control mechanism 3 into reciprocating motion. a conversion mechanism 4; and the rotation control mechanism 3 includes a rotation device 31; a connecting rod 32 coaxially connected to the rotating device 31, rotated by the rotating device 31, and vertically disposed in parallel with the heat radiation pipe 1; A gear 33 coupled to the connecting rod 32 and rotating together with the connecting rod 32, the rotation-parallel movement conversion mechanism 4 meshes with the gear 33 to a rack gear 41 that moves in the forward and backward directions when the gear 33 rotates; a fixed support 42 having one end connected to the heat radiation pipe 1 and the other end connected to the rack gear 41; A guide rail 43 supporting the fixed support 42 so that the fixed support 42 moves in the forward and backward directions; the length of the heat radiation tube 1 in the vertical direction of the reflector 2 longer than the length in the vertical direction, and the rotation control mechanism 3 is disposed behind the reflector 2 in the opposite direction to the heat radiation pipe 1 with respect to the reflector 2, and the rotation-parallel movement conversion The mechanism (4) is characterized in that the top or bottom of the reflector (2) is connected to the top or bottom of the heat radiation pipe (1).

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Further, the number of the moving mechanisms is one or plural, and when the moving mechanisms are plural, the plurality of moving mechanisms are respectively connected to different elevation positions of the heat radiation pipe.

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Further, the guide rail includes a pair of sliding grooves, and both sides of the fixed support are respectively inserted into the pair of sliding grooves and slidingly matched with the pair of sliding grooves.

Furthermore, the fixed support and the rack gear are integrally molded.

Further, the rotating device is a rotary knob (knlb).

Further, the rotating device is a motor.

Further, the heat radiation tube is a carbon tube.

The useful effects of the present invention are as follows. Since the heat dissipation tube can move under the linkage of the moving mechanism, different heat dissipation can be obtained under the premise that the output does not change when moved to a different position. When moving forward relative to the reflector focal length position, the column can be focused in front. Conversely, heat can be dissipated relatively uniformly when moving backward, and the user can select the position of the heat sink as needed. The present invention has advantages such as simple operation, high thermal efficiency, and economical energy saving.

1 is an exploded view of a movable heat radiation tube electric heater of Example 1;
Fig. 2 is a comparison diagram of the front and rear states when the movable heat radiation pipe electric heater of Example 1 moves backward from the heat radiation pipe.
3 is a comparison diagram of reflector reflected heat when the heat sink is in different positions.
Fig. 4 is a structural schematic diagram of the movable heat radiation tube electric heater of Embodiment 2;

In order to easily understand the contents of the present invention, the present invention is more comprehensively described with reference to the related drawings below. The drawings show typical embodiments of the present invention. However, the present invention is implemented in various forms, and is not limited to the embodiments described in the present invention. On the other hand, providing these examples aims to more clearly reveal the disclosure of the present invention.

Therefore, if an element is considered to be 'fixed' to another element, it should be explained that the element is directly located in another element or an element in the middle. If one element is considered to 'connect' another element, the element can be connected to another element or to an element in the middle at the same time. The technical terms 'vertical', 'horizontal', 'before', 'after' and similar expressions used in the present invention are used only for the purpose of explanation of the present invention.

Unless otherwise defined, all technical and scientific terms used in the present invention have the same meaning as can be understood by a person of ordinary skill in the art with common sense. The technical terms used in the specification of the present invention are only used for the purpose of describing specific embodiments, and are not limited to the present invention.

Referring to Figure 1, the features of the present invention are as follows. A moving mechanism is additionally installed in the movable heat sink electric heater, the heat sink 1 is connected to the moving mechanism, and moves to a position of the reflector 2 that is relatively closer in front of the focal point under the interlocking action of the moving mechanism. Or, it is moved to a position of the reflector 2 relatively further away from the rear. Therefore, different heat dissipation can be obtained under the premise that the output does not change when the heat sink 1 is moved to a different position. When moving forward relative to the position of the reflector 2 focal length, the column can be brought into focus at the front. Conversely, heat can be dissipated relatively uniformly when moving backward, and the user can select the position of the heat sink as needed. The present invention has advantages such as simple operation, high thermal efficiency, and economical energy saving.

In order to better understand the technical solution, the technical solution will be described in detail by combining specification drawings and specific embodiments. It should be noted that the embodiments of the present invention and specific features of the embodiments are intended to explain the technical solutions of the present invention in detail, and are not limited to the technical solutions of the present invention, and the embodiments of the present invention in situations where the contents of the present invention do not conflict. and technical features of the embodiments may be mutually combined.

Example 1

Referring to FIG. 1 , the movable heat radiation pipe electric heater of this embodiment includes a heat radiation pipe 1, a reflector 2, and a moving mechanism.

In this embodiment, the heat radiation tube 1 is a carbon tube. Of course, in other embodiments, a radial heat dissipation tube such as a quartz tube, a halogen tube, or a black tube may be used.

Here, the reflector 2 is installed toward the heat radiating tube 1 and is parallel to the heat radiating tube 1, and the cross section of the reflector 2 is generally a parabolic curved surface. It is implicitly acknowledged that the heat radiation pipe 1 is connected to the moving mechanism and the heat radiation pipe 1 is located at the focal point of the reflector 2 . The heat radiation pipe 1 is moved to a position of the reflector 2 relatively closer from the front of the focal point or to a position of the reflector 2 relatively farther from the rear under the interlocking action of the moving mechanism.

It should be understood that the number of the moving mechanism is one or plural. When there are a plurality of the moving mechanisms, the plurality of moving mechanisms are respectively connected to different elevation positions of the heat radiation tube 1 . For example, in this embodiment, to ensure that the upper and lower carbon tubes are synchronously moved, the number of moving mechanisms must be two, and the two moving mechanisms are connected to both ends of the heat radiation pipe 1, respectively.

Specifically, the movement mechanism includes a rotation control mechanism 3 and a rotation-parallel movement conversion mechanism 4. The rotation control mechanism 3 is used to realize rotational motion. The rotation-translation conversion mechanism 4 connects the rotation control mechanism 3 and the heat radiation pipe 1 respectively, and is used to convert the rotational motion of the rotation control mechanism 3 into a translational movement, The heat sink 1 is moved in parallel.

Here, the rotation-parallel movement conversion mechanism 4 is connected to the heat radiation pipe 1, and a rack gear 41 perpendicular to the heat radiation pipe 1, a fixed support 42, and the fixed support It includes a guide rail 43 supporting the 42. A fixed support 42 connects the rack gear 41 and the heat radiation pipe 1, respectively, and in this embodiment, the fixed support 42 and the rack gear 41 are integrally molded. The guide rail 43 and the fixed support 42 are slidingly matched. In this embodiment, the guide rail 43 includes a pair of sliding grooves, and both sides of the fixed support 42 are respectively paired with the sliding groove. It is inserted into the groove and slidingly matched with the pair of sliding grooves. That is, the sliding matching method of the fixed support 42 and the guide rail 43 is similar to a drawer type sliding.

Here, the rotation control mechanism 3 includes a rotating device 31, a connecting rod 32, and a gear 33. The rotation device 31 is specifically a rotation knob. The connecting rod 32 is fixed with the finished machine, the connecting rod 32 is parallel to the heat sink 1, and the connecting rod 32 and the heat sink 1 are connected to the central cut of the hyperfocal of the reflector 2 located on the side The connecting rod 32 and the rotating device 31 are coaxially connected, and are used to rotate under the driving of the rotating device 31 . The gear 33 is installed on the connecting rod 32 as a cover, meshes with the rack gear 41, and the gear 33 rotates together along the connecting rod 32.

In this embodiment, the two moving mechanisms share the same connecting rod 32 and the same rotating device 31 . The same connecting rod 32 and rotation device 31 are also used when installing a larger number of other moving mechanisms. Consequently, when there are a plurality of moving mechanisms, it is only necessary to add a corresponding number of gears 33 and rotation-parallel movement converting mechanisms 4.

The working principle of this embodiment is as follows. Referring to FIG. 2 , in the drawing on the left side of FIG. 2 , the heat sink 1 is in a focal position, and the corresponding heat reflection state is indicated in the middle of FIG. 3 . To move the heat sink 1 backward, the rotary knob must be rotated, and at this time, the gear 33 of the connecting rod 32 also rotates in accordance with this, and the gear 33 and the rack gear 41 mesh. Therefore, the rack gear 41 is moved backward in a straight line according to the rotation of the gear 33, so that the fixed support 42 is moved backward along the guide rail 43 and locked to the fixed support 42. The true heat sink 1 is also moved rearward. The drawing on the right in FIG. 2 is a structural diagram in which the heat sink 1 is moved to the rear of the focal point. The heat reflection state at this time is as shown in the left drawing of FIG. 3 . In the same principle, when moving the heat sink 1 forward, the rotary knob may be rotated in the opposite direction. At this time, the corresponding heat reflection state is as shown in the drawing on the right side of FIG. 3 .

Effects of this embodiment are as follows. Different heat dissipation can be obtained, provided that the heat sink 1 is free to move relative to the finished machine and does not change its output when moved to a different position. As shown in FIG. 4, when moving toward the front of the aircraft relative to the focus position of the reflector 2, the column can be focused on the front. Conversely, heat can be dissipated relatively uniformly when moving backward, and the user can select the position of the heat sink as needed. The present invention has advantages such as simple operation, high thermal efficiency, and economical energy saving.

Example 2

Referring to FIG. 4 , the difference between the present embodiment and the first embodiment is revealed in that the rotary device 31 is no longer a rotary knob but a motor. Therefore, electrical control of the movable heat radiation pipe 1 can be realized.

The above information has been described an embodiment of the present invention by combining the drawings. However, the present invention is not limited to the specific embodiments, and the specific embodiments are illustrative only and not limiting. Therefore, those skilled in the art can present various forms within the disclosed technical scope of the present invention without departing from the scope of the object and claims of the present invention, which fall within the protection scope of the present invention.

1: heat sink
2: reflector
3: rotation control mechanism
4: rotation-translation conversion mechanism
31: rotation device
32: connection rod
33: gear
41: rack gear
42: fixed support
43: guide rail

Claims (10)

a rod-shaped heat dissipation pipe 1 extending in the vertical direction;
a reflector (2) disposed at the rear of the heat radiation pipe (1) and formed long in the vertical direction while forming a curved shape with both sides curved forward;
A moving mechanism for moving the heat radiation pipe 1 in the forward and backward directions with respect to the reflector 2;
The moving mechanism,
a rotation control mechanism 3 used for rotational motion;
Rotation-parallel movement that connects the rotation control mechanism 3 and the heat radiation tube 1 and moves the heat radiation tube 1 forward and backward while converting the rotational motion of the rotation control mechanism 3 into reciprocating motion. The conversion mechanism (4); consists of,
The rotation control mechanism 3,
a rotating device 31;
a connecting rod 32 coaxially connected to the rotating device 31, rotated by the rotating device 31, and vertically disposed in parallel with the heat radiation pipe 1;
A gear 33 coupled to the connecting rod 32 and rotating together with the connecting rod 32;
The rotation-translation conversion mechanism 4,
a rack gear 41 engaged with the gear 33 and moving forward and backward when the gear 33 rotates;
a fixed support 42 having one end connected to the heat radiation pipe 1 and the other end connected to the rack gear 41;
A guide rail 43 supporting the fixed support 42 so that the fixed support 42 moves in the front and rear directions;
The vertical length of the heat radiation pipe 1 is longer than the vertical length of the reflector 2,
The rotation control mechanism 3 is disposed behind the reflector 2 in the opposite direction to the heat radiation pipe 1 based on the reflector 2,
The rotation-to-parallel movement conversion mechanism (4) is connected to the top or bottom of the heat pipe (1) from the top or bottom of the reflector (2). According to claim 1,
The number of moving mechanisms is plural,
The movable heat-radiating tube electric heater, characterized in that the plurality of moving mechanisms are respectively connected to the upper and lower portions of the heat-radiating tube (1) from the outside of the reflector (2). delete delete delete According to claim 1,
The guide rail 43 includes a pair of sliding grooves, and both sides of the fixed support 42 are respectively inserted into the pair of sliding grooves and slidingly matched with the pair of sliding grooves. Tubular electric stove. According to claim 1,
The movable heat radiation pipe electric stove, characterized in that the fixed support (42) and the rack gear (41) are integrally molded. According to claim 1,
A movable heat radiation tube electric stove, characterized in that the rotating device (31) is a rotary knob (konb). According to claim 1,
The movable heat radiation pipe electric stove, characterized in that the rotating device (31) is a motor. According to claim 1,
A movable heat radiation tube electric stove, characterized in that the heat radiation tube (1) is a carbon tube.

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