CN217427865U - Adjustable motor for running machine - Google Patents

Abstract

The utility model provides an adjustable motor for a treadmill, which comprises a motor body; the fixed plate is arranged at the top of the power cabin; the moving part and the fixed plate are oppositely arranged, and a telescopic part is arranged between the moving part and the fixed plate; the sliding vertical plate is arranged at the bottom of the moving part in a sliding manner; the motor body is arranged on the side wall of the sliding vertical plate; in short, by arranging the fixing plate at the top of the power cabin, an adjustable motor can be arranged on the fixing plate; the movable part can complete the adjustment of the position in the vertical direction through the arrangement of the movable part and the telescopic part; the adjustment of the motor body in the horizontal direction can be realized through the arrangement of the sliding vertical plate and the motor body; it should be noted that the power pod is the location where the power elements are located, and is typically located on the head of the treadmill, and a housing is located above the power pod.

Description

Adjustable motor for running machine

Technical Field

The utility model relates to a motor field, concretely relates to motor with adjustable treadmill is used.

Background

The treadmill is a commonly-used fitness device for families and fitness rooms, is the simplest one of the current family fitness devices, and is the best choice of the family fitness device. The first household running machine was born in the world in the 1965 by the Thangli force of North Europe, and designers were changed according to the principle of the transmission belt; the birth of the running machine represents a real domestic running machine in the modern sense, and people in European and American countries begin to accept running at home. However, the initial treadmill can only walk quickly on the treadmill, and the running is somewhat uncomfortable; the mechanical running machine is driven by the friction force between the feet of a runner and the running belt to run, and the electric running machine is simply driven by the motor to run;

as shown in fig. 1, when the treadmill is produced, there is a power compartment, in which a motor is installed, and the motor is usually fixed by a mounting seat, but when the treadmill with different specifications is produced, the position of the motor needs to be adjusted, so it is necessary to provide an adjustable motor for treadmill, which can quickly adjust the position of the motor.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: the adjustable motor for the treadmill can quickly adjust the position of the motor.

The utility model provides a technical scheme that its technical problem adopted is: an adjustable motor for a treadmill, comprising; the fixed plate is arranged at the top of the power cabin; the moving part and the fixed plate are oppositely arranged, and a telescopic part is arranged between the moving part and the fixed plate; the sliding vertical plate is arranged at the bottom of the moving part in a sliding manner; the motor body is arranged on the side wall of the sliding vertical plate.

Preferably, the moving part comprises a moving plate, and the telescopic part is arranged at the bottom of the moving plate; a sliding transverse plate extends from the side wall of the moving plate; the bottom of the sliding transverse plate is provided with a pair of parallel sliding vertical grooves, the top of each sliding vertical groove is provided with a sliding transverse groove communicated with the corresponding sliding vertical groove, and the communicated sliding vertical grooves and the corresponding sliding transverse grooves are arranged in parallel; the top of the sliding vertical plate is provided with a pair of sliding vertical columns matched with the sliding vertical grooves, and the top of each sliding vertical column is integrally provided with a sliding transverse block matched with the sliding transverse groove; the width of the sliding transverse groove is greater than that of the sliding vertical groove; the length of the sliding transverse groove is equal to that of the sliding vertical groove.

Preferably, the thickness of the sliding transverse plate is smaller than that of the moving plate, the cross section of the sliding transverse groove is rectangular, the cross section of the sliding vertical groove is rectangular, one end of the sliding transverse groove penetrates through the side wall of the moving plate, and the other end of the sliding transverse groove does not penetrate through the side wall of the sliding transverse plate.

Preferably, the telescopic part comprises a first hinge arm and a second hinge arm which are arranged in a crossed manner, and the midpoint of the first hinge arm and the midpoint of the second hinge arm are hinged through a pin shaft; one end of the first hinge arm, which is far away from the motor body, is hinged to the top of the fixed plate, and one end of the second hinge arm, which is far away from the motor body, is hinged to the bottom of the moving plate; a first sliding frame is arranged at the bottom of the moving plate, a first sliding groove is formed in the first sliding frame, and one end, close to the motor body, of the first hinged arm is clamped in the first sliding groove; the top of fixed plate is provided with the second sliding frame, it has the second sliding tray to open in the second sliding frame, the second articulated arm is close to the one end card of motor body is established in the second sliding tray.

Preferably, the first hinge arm is provided with a hinge notch, the second hinge arm passes through the hinge notch, and a hinge point of the first hinge arm and the second hinge arm is arranged in the hinge notch; a first notch is formed in one end, close to the motor body, of the first hinge arm, a first moving block is hinged in the first notch through a hinge pin, and the top and the bottom of the first moving block are attached to the top and the bottom of the first sliding groove respectively; a second notch is formed in one end, close to the motor body, of the second hinged arm, a second moving block is connected in the second notch in a cross mode through a hinge pin, and the top and the bottom of the second moving block are attached to the top and the bottom of the second sliding groove respectively.

Preferably, the first sliding frame comprises a first cover plate and a first base integrally arranged with the moving plate, the first base is in a shape of a C, an opening of the first base is downward, and the first cover plate covers the opening of the first base through a bolt; the second sliding frame comprises a second cover plate and a second base integrally arranged with the fixing plate, the second base is C-shaped, the opening of the second base faces upwards, and the second cover plate covers the opening of the second base through a bolt.

Preferably, a through hole is formed in the side wall, close to the motor body, of the first base, a first stud is rotatably arranged in the through hole, and a first threaded sleeve matched with the first bolt is integrally arranged on the side wall of the sliding vertical plate; a clamping ring is integrally arranged on the first stud, and two pairs of flat positions are equidistantly arranged on the circumferential side wall of the clamping ring; two first compression rings are in threaded connection with the first stud.

Preferably, a threaded hole is formed in the side wall, close to the motor body, of the second base, a second stud is rotatably arranged on the second moving block, the other end of the second stud is connected in the threaded hole in a threaded manner, and two second compression rings are arranged on the second stud.

Preferably, the two second compression rings are arranged on the same side of the second base, which is close to the side wall of the motor body.

The beneficial effects of the utility model are that:

1. the fixing plate is arranged at the top of the power cabin, and an adjustable motor can be arranged on the fixing plate;

2. the movable part can complete the adjustment of the position in the vertical direction through the arrangement of the movable part and the telescopic part; 3. through the setting of slip riser and motor body, can realize motor body's horizontal direction's regulation.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a prior art fixed structure of a motor in a treadmill;

FIG. 2 is a fixed structure view of the motor body of the present invention in the running machine;

fig. 3 is a perspective view of the adjustable motor of the present invention;

fig. 4 is an exploded view of the adjustable motor of the present invention;

fig. 5 is an exploded view of the sliding vertical plate of the present invention.

In the figure:

000. a power compartment;

100. a fixing plate;

200. a moving part; 201. moving the plate; 202. sliding the transverse plate; 2021. a sliding vertical slot; 2022. a sliding transverse slot; 203. a first slide frame; 2031. a first sliding groove; 2032. a first cover plate; 2033. a first base; 2034. a first stud; 2035. a clamping ring; 2036. a first clamp ring; 204. a second sliding frame; 2041. a second sliding groove; 2042. a second cover plate; 2043. a second base; 2044. a second stud; 2045. a second clamp ring;

300. a telescopic part; 301. a first hinge arm; 3011. a hinge notch; 3012. a first notch; 3013. a first moving block; 302. a second hinge arm; 3021 a second notch; 3022. a second moving block;

400. sliding the vertical plate; 401. sliding the upright post; 402. sliding the transverse block; 403. a first threaded sleeve;

500. the motor body.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings, and are used only for convenience in describing and simplifying the present invention, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art. In addition, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

As shown in fig. 1-5, the present invention provides an adjustable motor for a treadmill, comprising; a fixed plate 100, wherein the fixed plate 100 is arranged at the top of the power compartment 000; a moving part 200, the moving part 200 and the fixed plate 100 being disposed opposite to each other, and a telescopic part 300 being disposed between the moving part 200 and the fixed plate 100; the sliding vertical plate 400 is arranged at the bottom of the moving part 200 in a sliding manner; the motor body 500 is arranged on the side wall of the sliding vertical plate 400; in short, by the fixing plate 100 being disposed on the top of the power compartment 000, an adjustable motor can be disposed on the fixing plate 100; the arrangement of the moving part 200 and the telescopic part 300 can enable the moving part 200 to complete the adjustment of the position in the vertical direction; the adjustment of the motor body 500 in the horizontal direction can be realized by the arrangement of the sliding vertical plate 400 and the motor body 500; it should be noted that the power pod 000 is the location where the power components are located, and is typically located on the head of the treadmill, and a housing is located above the power pod 000.

The moving part 200 comprises a moving plate 201, and the telescopic part 300 is arranged at the bottom of the moving plate 201; a sliding transverse plate 202 extends from the side wall of the moving plate 201; the bottom of the sliding transverse plate 202 is provided with a pair of parallel sliding vertical grooves 2021, the top of the sliding vertical groove 2021 is provided with a sliding transverse groove 2022 communicated with the sliding vertical groove 2021, and the communicated sliding vertical groove 2021 and the sliding transverse groove 2022 are arranged in parallel; the top of the sliding vertical plate 400 is provided with a pair of sliding upright posts 401 adapted to the sliding vertical grooves 2021, and the top of the sliding upright posts 401 is integrally provided with sliding transverse blocks 402 adapted to the sliding transverse grooves 2022; the width of the sliding transverse groove 2022 is greater than that of the sliding vertical groove 2021; the length of the sliding transverse groove 2022 is equal to the length of the sliding vertical groove 2021; in short, the sliding horizontal block 402 can slide in the sliding horizontal groove 2022, and the sliding upright column 401 can slide in the sliding vertical groove 2021, so that the sliding upright 400 can realize the adjustment of the horizontal position, the structure is simple and reliable, and the use convenience is improved.

The thickness of the sliding transverse plate 202 is smaller than that of the moving plate 201, the cross section of the sliding transverse groove 2022 is rectangular, the cross section of the sliding vertical groove 2021 is rectangular, one end of the sliding transverse groove 2022 penetrates through the side wall of the moving plate 201, and the other end of the sliding transverse groove 2022 does not penetrate through the side wall of the sliding transverse plate 202; in short, the thickness of the sliding horizontal plate 202 is smaller than that of the moving plate 201, so that the side wall of the moving plate 201 can close the sliding vertical groove 2021, and further, the sliding horizontal groove 2022 and one end of the sliding vertical groove 2021 can avoid the sliding vertical plate 400 from sliding out of the sliding vertical groove 2021 regardless of the side wall passing through the sliding horizontal plate 202.

The telescopic part 300 comprises a first hinge arm 301 and a second hinge arm 302 which are arranged in a crossed manner, wherein the midpoint of the first hinge arm 301 and the midpoint of the second hinge arm 302 are hinged through a pin shaft; one end of the first hinge arm 301, which is far away from the motor body 500, is hinged on the top of the fixed plate 100, and one end of the second hinge arm 302, which is far away from the motor body 500, is hinged on the bottom of the moving plate 201; a first sliding frame 203 is arranged at the bottom of the moving plate 201, a first sliding groove 2031 is formed in the first sliding frame 203, and one end of the first hinge arm 301 close to the motor body 500 is clamped in the first sliding groove 2031; a second sliding frame 204 is arranged at the top of the fixing plate 100, a second sliding groove 2041 is formed in the second sliding frame 204, and one end of the second hinge arm 302 close to the motor body 500 is clamped in the second sliding groove 2041; in short, by the arrangement of the first sliding groove 2031 and the second sliding groove 2041, the first hinge arm 301 and the second hinge arm 302 can slide in the first sliding groove 2031 and the second sliding groove 2041, respectively, so that the first hinge arm 301 and the second hinge arm 302 can be expanded and contracted to adjust the position of the moving plate 201 in the vertical direction, the structure is simple and reliable, and the use convenience is improved.

A hinge notch 3011 is formed on the first hinge arm 301, the second hinge arm 302 passes through the hinge notch 3011, and a hinge point of the first hinge arm 301 and the second hinge arm 302 is disposed in the hinge notch 3011; a first notch 3012 is formed in one end, close to the motor body 500, of the first hinge arm 301, a first moving block 3013 is hinged in the first notch 3012 through a hinge pin, and the top and the bottom of the first moving block 3013 are respectively attached to the top and the bottom of the first sliding groove 2031; a second notch is formed in one end, close to the motor body 500, of the second hinge arm 302, and a second notch of a second moving block 3021 is cross-connected in the second notch through a pin shaft; 3022, the second moving block 3021 has a second notch; 3022 the top and bottom of the second sliding groove 2041 fit into the top and bottom of the first sliding groove, respectively; in short, by the hinge notch 3011, the second hinge arm 302 can be inserted into the first hinge arm 301 to reduce the volume of the telescopic part 300; further, by the horizontal sliding of the first sliding block and the second sliding block, the hinge point of the first hinge arm 301 and the second hinge arm 302 can be moved up and down, so that the moving plate 201 can be moved up and down to adjust the height of the motor body 500;

the first sliding frame 203 includes a first cover plate 2032 and a first base 2033 integrally disposed with the moving plate 201, the first base 2033 is C-shaped, an opening of the first base 2033 faces downward, and the first cover plate 2032 is covered on the opening of the first base 2033 by a bolt; the second sliding frame 204 includes a second cover plate 2042 and a second base 2043 integrally disposed with the fixing plate 100, the second base 2043 is C-shaped, an opening of the second base 2043 is upward, and the second cover plate 2042 is covered on the opening of the second base 2043 through a bolt; in short, the first cover plate 2032 and the first base 2033 are separately arranged, so that the first moving block 3013 can be conveniently mounted, further, the first notch 3012 is shaped like a cuboid, and the first moving block 3013 adapted to the first notch 3013 is also shaped like a cuboid, so that the first moving block 3013 can be prevented from sliding in the first notch 3012 and rotating; the second notch is in a cuboid shape, and a second notch of a second moving block 3021 is matched with the second notch; 3022 the second moving block 3021 is also rectangular, so that a second notch can be avoided; 3022 sliding in the second notch to rotate;

a through hole is formed in the side wall of the first base 2033 close to the motor body 500, a first stud 2034 is rotatably arranged in the through hole, and a first threaded sleeve 403 matched with the first bolt is integrally arranged on the side wall of the sliding vertical plate 400; a clamping ring 2035 is integrally arranged on the first stud 2034, and two pairs of flat positions are equidistantly arranged on the circumferential side wall of the clamping ring 2035; two first compression rings 2036 are in threaded connection with the first stud 2034; in short, the first stud 2034 can be rotated through a flat position, so that the first threaded sleeve 403 can be horizontally moved to adjust the position of the sliding vertical plate 400; furthermore, first stud 2034 can be tightened by first compression ring 2036, so as to prevent first stud 2034 from rotating when motor body 500 is in operation.

A threaded hole is formed in the side wall of the second base 2043 close to the motor body 500, and a second gap is formed in the second moving block 3021; 3022 a second stud 2044 is rotatably arranged on the base, the other end of the second stud 2044 is screwed in the threaded hole, and two second compression rings 2045 are arranged on the second stud 2044; in short, through the threaded connection between the threaded hole and the second stud 2044, when the second stud 2044 is rotated, the second moving distance can be adjusted, so that the height of the moving plate 201 can be adjusted, and the structure is simple and reliable; furthermore, the second stud 2044 can be fastened by the second compression ring 2045, so that the effect of fixing the second stud 2044 is achieved.

The two second compression rings 2045 are arranged on the same side of the second base 2043 close to the side wall of the motor body 500; in short, two second compression rings 2045 are disposed on the same side, so that the second compression ring 2045 can compress the first second compression ring 2045, further fastening the second stud 2044.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the description, and must be determined according to the scope of the claims.

Claims (9)

1. An adjustable motor for a treadmill is characterized by comprising;

a fixed plate (100), wherein the fixed plate (100) is arranged at the top of the power cabin (000);

a moving part (200), wherein the moving part (200) and the fixed plate (100) are arranged oppositely, and a telescopic part (300) is arranged between the moving part (200) and the fixed plate (100);

the sliding vertical plate (400), the sliding vertical plate (400) is arranged at the bottom of the moving part (200) in a sliding manner;

the motor body (500), the motor body (500) is arranged on the side wall of the sliding vertical plate (400).

2. The adjustable motor for a treadmill of claim 1,

the moving part (200) comprises a moving plate (201), and the telescopic part (300) is arranged at the bottom of the moving plate (201);

a sliding transverse plate (202) extends from the side wall of the moving plate (201); the bottom of the sliding transverse plate (202) is provided with a pair of parallel sliding vertical grooves (2021), the top of each sliding vertical groove (2021) is provided with a sliding transverse groove (2022) communicated with the corresponding sliding vertical groove (2021), and the communicated sliding vertical grooves (2021) and the corresponding sliding transverse grooves (2022) are arranged in parallel;

the top of the sliding vertical plate (400) is provided with a pair of sliding upright columns (401) matched with the sliding vertical grooves (2021), and the top of each sliding upright column (401) is integrally provided with a sliding transverse block (402) matched with the sliding transverse groove (2022);

the width of the sliding transverse groove (2022) is greater than that of the sliding vertical groove (2021); the length of the sliding transverse groove (2022) is equal to that of the sliding vertical groove (2021).

3. The adjustable motor for a treadmill of claim 2,

the thickness of the sliding transverse plate (202) is smaller than that of the moving plate (201), the section of the sliding transverse groove (2022) is rectangular, the section of the sliding vertical groove (2021) is rectangular, one end of the sliding transverse groove (2022) penetrates through the side wall of the moving plate (201), and the other end of the sliding transverse groove (2022) does not penetrate through the side wall of the sliding transverse plate (202).

4. The adjustable motor for a treadmill of claim 3,

the telescopic part (300) comprises a first hinge arm (301) and a second hinge arm (302) which are arranged in a crossed mode, and the middle point of the first hinge arm (301) and the middle point of the second hinge arm (302) are hinged through a pin shaft;

one end of the first hinge arm (301) far away from the motor body (500) is hinged on the top of the fixed plate (100), and one end of the second hinge arm (302) far away from the motor body (500) is hinged on the bottom of the moving plate (201);

a first sliding frame (203) is arranged at the bottom of the moving plate (201), a first sliding groove (2031) is formed in the first sliding frame (203), and one end, close to the motor body (500), of the first hinge arm (301) is clamped in the first sliding groove (2031);

the top of fixed plate (100) is provided with second sliding frame (204), set up second sliding tray (2041) in second sliding frame (204), second articulated arm (302) are close to the one end card of motor body (500) is established in second sliding tray (2041).

5. The adjustable motor for a treadmill of claim 4,

a hinge notch (3011) is formed in the first hinge arm (301), the second hinge arm (302) penetrates through the hinge notch (3011), and a hinge point of the first hinge arm (301) and the second hinge arm (302) is arranged in the hinge notch (3011);

a first notch (3012) is formed in one end, close to the motor body (500), of the first hinged arm (301), a first moving block (3013) is hinged to the first notch (3012) through a pin shaft, and the top and the bottom of the first moving block (3013) are attached to the top and the bottom of the first sliding groove (2031) respectively;

one end, close to the motor body (500), of the second hinged arm (302) is provided with a second notch, a second moving block (3021, a second notch; 3022) is connected in the second notch in a crossed mode through a pin shaft, and the top and the bottom of the second moving block (3021, the second notch; 3022) are attached to the top and the bottom of the second sliding groove (2041) respectively.

6. The adjustable motor for a treadmill of claim 5,

the first sliding frame (203) comprises a first cover plate (2032) and a first base (2033) which is integrally arranged with the moving plate (201), the first base (2033) is C-shaped, the opening of the first base (2033) faces downwards, and the first cover plate (2032) is covered at the opening of the first base (2033) through bolts;

the second sliding frame (204) comprises a second cover plate (2042) and a second base (2043) integrally arranged with the fixed plate (100), the second base (2043) is C-shaped, an opening of the second base (2043) is upward, and the second cover plate (2042) is covered at the opening of the second base (2043) through bolts.

7. The adjustable motor for a treadmill of claim 6,

a through hole is formed in the side wall, close to the motor body (500), of the first base (2033), a first stud (2034) is rotatably arranged in the through hole, and a first threaded sleeve (403) matched with the first stud is integrally arranged on the side wall of the sliding vertical plate (400); a clamping ring (2035) is integrally arranged on the first stud (2034), and two pairs of flat positions are equidistantly arranged on the circumferential side wall of the clamping ring (2035); two first compression rings (2036) are in threaded connection with the first stud (2034).

8. The adjustable motor for a treadmill of claim 7,

the side wall of the second base (2043), which is close to the motor body (500), is provided with a threaded hole, the second moving block (3021 is provided with a second notch, 3022) is provided with a second stud (2044) in a rotating manner, the other end of the second stud (2044) is connected in the threaded hole in a threaded manner, and the second stud (2044) is provided with two second compression rings (2045).

9. The adjustable motor for a treadmill of claim 8,

the two second compression rings (2045) are arranged on the same side of the second base (2043) close to the side wall of the motor body (500).

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