CN220819182U - Horizontal adjustment foot structure and electronic scale using same - Google Patents

Abstract

The utility model discloses a horizontal adjusting foot structure and an electronic scale using the same, comprising supporting feet and elastic pieces, wherein the upper side surface of the elastic deformation end of the elastic piece is provided with a gasket, the lower side surface of the elastic deformation end of the elastic piece is provided with a force transmission piece, the elastic deformation end of the elastic piece and the gasket are connected through screws, the bottom surface of the force transmission piece is provided with a force transmission piece concave hole, a nut is embedded in the force transmission piece concave hole, the top of the supporting feet is connected with a screw rod in threaded connection with the nut, meanwhile, a plurality of weighing sensors are arranged in the electronic scale body, the elastic pieces are fixed in the scale body, and the upper side surface of the gasket arranged on the upper side of the elastic deformation end of the elastic piece is contacted with the detection end of the weighing sensors, so that the scale body is used in use scenes of different height difference planes, and the weighing accuracy and the use experience of the electronic scale are improved.

Description

Horizontal adjustment foot structure and electronic scale using same

[ Technical field ]

The utility model relates to a horizontal adjusting foot structure and an electronic scale using the same.

[ Background Art ]

In the electronic scale products on the current market, an elastic piece mechanism is mostly adopted and is connected with an elastic piece through supporting legs, when a scale body is placed on a plane with a small height difference, the elastic piece can be adjusted in a self-adaptive mode, weighing influence caused by the small height difference of a placing platform is eliminated, but when the plane has a larger height difference exceeding the deformation amount of the elastic piece, the scale body cannot be placed horizontally.

[ Summary of the utility model ]

The utility model overcomes the defects of the prior art and provides a horizontal adjusting foot structure and an electronic scale using the foot structure.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

A horizontal adjustment foot structure, characterized in that: the support leg comprises a support leg and an elastic piece, wherein a gasket is arranged on the upper side face of an elastic deformation end of the elastic piece, a force transmission piece is arranged on the lower side face of the elastic deformation end of the elastic piece, the elastic deformation ends of the force transmission piece and the gasket are connected through screws, a force transmission piece concave hole is formed in the bottom face of the force transmission piece, a nut is embedded in the force transmission piece concave hole, and the top of the support leg is connected with a screw rod in threaded connection with the nut.

A horizontal adjustment foot structure as described above, wherein: the elastic piece is including annular base, is equipped with deformation connecting portion in the annular base, is connected with a plurality of elastic arms between annular base inboard side and the deformation connecting portion outside side, and the gasket sets up in deformation connecting portion upside, passes power setting at deformation connecting portion downside, screw fixed connection gasket, deformation connecting portion and passes power.

A horizontal adjustment foot structure as described above, wherein: the deformation connecting portion is equipped with connecting portion recess in the side, and the gasket sets up in the connecting portion recess.

A horizontal adjustment foot structure as described above, wherein: the outer side surface of the annular base is provided with a plurality of connecting convex blocks, and convex block through holes are arranged on the connecting convex blocks.

A horizontal adjustment foot structure as described above, wherein: the inner side surface of the concave hole of the force transmission piece is provided with an annular positioning convex block, and the outer side surface of the nut is provided with an annular positioning groove matched with the annular positioning convex block.

A horizontal adjustment foot structure as described above, wherein: the bottom surface of the force transmission piece is provided with a force transmission piece convex column, and the force transmission piece concave hole is arranged on the bottom surface of the force transmission piece convex column.

A horizontal adjustment foot structure as described above, wherein: the bottom surface of the supporting leg is provided with an anti-slip pad.

An electronic scale applying the horizontal adjusting foot structure is characterized in that: the balance comprises a balance body, wherein a plurality of weighing sensors are arranged in the balance body, an elastic piece is fixed in the balance body, and the upper side surface of a gasket arranged on the upper side of an elastic deformation end of the elastic piece is contacted with the detection end of the weighing sensors.

The electronic scale as described above, wherein: the balance body comprises a surface shell and a bottom shell, wherein a control board groove is formed in the inner side of the surface shell, a control board which is connected with a weighing sensor and used for calculating and displaying weighing data is arranged in the control board groove, a sealing ring is arranged between the opening end of the control board groove and the inner side surface of the bottom shell, the weighing sensor is arranged on the inner side of the surface shell, and an elastic piece is fixed on the surface shell.

The electronic scale as described above, wherein: at least one handle through hole is arranged on the balance body.

The beneficial effects of the utility model are as follows:

According to the electronic scale, the elastic piece of the elastic cantilever is arranged on the bottom shell of the scale body, the force transmission piece is arranged on the elastic piece, the force transmission piece concave hole is formed in the bottom surface of the force transmission piece, the nut is embedded in the force transmission piece concave hole, the top of the supporting leg is connected with the screw rod in threaded connection with the nut, the horizontal adjusting function of large height difference of the placing plane is realized through the cooperation of the screw rod and the nut, and the horizontal self-adaptive adjusting function of the scale body placed on the small height difference plane is realized through the elastic piece, so that the scale body is suitable for complex and various use scenes, and the weighing accuracy and the use experience of the electronic scale are improved.

[ Description of the drawings ]

FIG. 1 is a schematic view of a leveling foot of the present utility model;

FIG. 2 is one of the exploded views of the leveling foot of the present utility model;

FIG. 3 is a second exploded view of the horizontal adjustment foot of the present utility model;

FIG. 4 is a third exploded view of the horizontal adjustment foot of the present utility model;

FIG. 5 is a cross-sectional view of a horizontal adjustment foot of the present utility model;

FIG. 6 is a schematic diagram of an electronic scale according to the present utility model;

FIG. 7 is a second schematic diagram of the electronic scale of the present utility model;

FIG. 8 is one of the exploded views of the electronic scale of the present utility model;

FIG. 9 is a second exploded view of the electronic scale of the present utility model.

Detailed description of the preferred embodiments

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings.

It should be noted that all directional indicators such as up, down, left, right, front, and rear … in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a specific posture such as that shown in the drawings, and if the specific posture is changed, the directional indicator is changed accordingly. Furthermore, the description of "preferred," "less preferred," and the like, herein is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "preferred", "less preferred" may include at least one such feature, either explicitly or implicitly.

As shown in fig. 1-5, a horizontal adjusting leg structure of an electronic scale comprises a supporting leg 1 and an elastic piece 2 fixed in the scale body, wherein the elastic piece 2 is specifically an elastic cantilever component, a gasket 3 is arranged on the upper side face of an elastic deformation end of the elastic piece 2, the upper side face of the gasket 3 is in contact with a detection end of a weighing sensor, a force transmission piece 4 is arranged on the lower side face of the elastic deformation end of the elastic piece 2, the force transmission piece 4, the elastic deformation end of the elastic piece 2 and the gasket 3 are connected through a screw 5, a force transmission piece concave hole 41 is formed in the bottom face of the force transmission piece 4, a nut 6 is embedded in the force transmission piece concave hole 41, and a screw 7 in threaded connection with the nut 6 is connected to the top of the supporting leg 1.

During assembly, the gasket 3 and the force transferring piece 4 are respectively placed on the upper side surface and the lower side surface of the elastic deformation end of the elastic piece 2, and sequentially pass through the force transferring piece 4, the elastic deformation end of the elastic piece 2 and the gasket 3 through the screw 5, so that the gasket 3, the elastic piece 2 and the gasket 3 are fixedly connected, then the elastic piece 2 is fixed on the bottom shell of the balance body, the upper side surface of the gasket 3 is contacted with the detection end of the weighing sensor of the balance body in a non-deformation state of the elastic piece 2, and finally the support leg 1 is in threaded connection with the force transferring piece 4 through the matching of the screw 7 and the nut 6 embedded in the concave hole 41 of the force transferring piece. When adjusting the balance body levelness, can rotate each supporting legs 1 earlier according to placing planar difference in height, adjust each supporting legs 1's height respectively under screw rod 7 and nut 6 threaded connection cooperation, realized big difference in height and placed planar balance body levelness regulatory function, place the balance body later on placing the plane, each supporting legs 1 is through passing through power piece 4 under elastic component 2 elastic force effect, respectively self-adaptation regulation balance body levelness to realized that the balance body is placed and can keep the level in the use scene homoenergetic of different difference in height and place the function, and improved the weighing accuracy and the use experience of electronic scale.

As shown in fig. 1-5, the elastic member 2 includes an annular base 21 fixedly connected with a bottom shell of the scale body, a deformation connecting portion 22 is disposed in the annular base 21, a plurality of elastic arms 23 are connected between an inner side surface of the annular base 21 and an outer side surface of the deformation connecting portion 22, the gasket 3 is disposed on an upper side surface of the deformation connecting portion 22, the force transmission member 4 is disposed on a lower side surface of the deformation connecting portion 22, the screw 5 is fixedly connected with the gasket 3, the deformation connecting portion 22 and the force transmission member 4, and the elastic arms 23 are disposed four and uniformly distributed between the annular base 21 and the deformation connecting portion 22 to provide uniform and sufficient elastic force.

As shown in fig. 1-2 and fig. 5, the upper side of the deformation connection part 22 is provided with a connection part groove 221, the gasket 3 is arranged in the connection part groove 221, and the gasket 3 is positioned and installed, so that the screw 5 can be connected quickly; the gasket 3 is a metal gasket. When weighing, the elastic piece 2 deforms to enable the gasket 3 to extrude the detection end of the weighing sensor to generate weighing data, the metal gasket is convenient for the screw 5 to be connected and locked, meanwhile, accurate weighing pressure is transmitted for the detection end of the weighing sensor, and the accuracy of the weighing data of the weighing sensor is improved.

As shown in fig. 1-5, the outer side surface of the annular base 21 is provided with a plurality of connection lugs 24, the connection lugs 24 are provided with lug through holes 241, the annular base 21 is fixed on the bottom shell of the scale body by matching screws with the lug through holes 241, wherein the connection lugs 24 are provided with three and are uniformly arranged on the outer side surface of the annular base 21, so that the annular base 21 is stably and fixedly arranged on the bottom shell of the scale body, and is more uniformly stressed during weighing deformation.

As shown in fig. 4, an annular positioning protruding block 411 is arranged on the inner side surface of the force transmission member concave hole 41, an annular positioning groove 61 matched with the annular positioning protruding block 411 is arranged on the outer side surface of the nut 6, and the nut 6 is positioned and embedded in the force transmission member concave hole 41 during production, so that the nut 4 is prevented from being separated from the force transmission member concave hole 41.

As shown in fig. 1-5, the bottom surface of the force-transmitting member 4 is provided with a force-transmitting member boss 42, and the force-transmitting member recess 41 is provided on the bottom surface of the force-transmitting member boss 42, so as to facilitate the installation of the nut 6 in the force-transmitting member 4 and provide a sufficient space for the screw 7 to extend into the force-transmitting member 4.

As shown in fig. 1-5, the number of the screws 5 is three and the screws are uniformly and respectively arranged on the bottom surface of the force transmission piece 4 outside the convex column 42 of the force transmission piece, so that the gasket 3, the deformation connecting part 22 and the force transmission piece 4 are firmly connected; the side of the boss 42 of the force-transmitting member is provided with a relief notch 43 near the screw 5 for facilitating the rotation of the screw 5 using a screwdriver.

As shown in fig. 5, the bottom surface of the supporting leg 1 is provided with an anti-slip pad 8 to prevent the scale body from sliding backwards.

As shown in fig. 6-9, an electronic scale using the above-mentioned horizontal adjustment leg structure includes a scale body 9, wherein a plurality of weighing sensors 10 are disposed in the scale body 9, an elastic member 2 is fixed in the scale body 9, and the upper side surface of a spacer 3 disposed on the upper side of an elastically deformed end of the elastic member 2 is in contact with the detection end of the weighing sensors 10; the scale body 9 comprises a surface shell 91 and a bottom shell 92, a control panel groove 911 is formed in the inner side of the surface shell 91, and a control panel 11 which is connected with the weighing sensor 10 and used for calculating and displaying weighing data is arranged in the control panel groove 911; four weighing sensors 10 and four horizontal adjusting feet respectively contacted with the weighing sensors 10 are arranged on the electronic scale. When the electronic scale weighs after adjusting the level degree, a weighing object is placed on the face shell 91 of the scale body 9, the supporting legs 1 are stressed, the detection ends of the weighing sensors 10 are deformed through the force transmission piece 4 and the gasket 3 to generate weighing signals, the weighing signals are sent to the control board 11, the control board 11 displays weighing data after calculation, meanwhile, the control board 11 also has a Bluetooth communication function, and can be connected with electronic equipment in a wireless communication mode to send the weighing data.

As shown in fig. 8 to 9, the inner side surface of the face case 91 is provided with a sensor mounting groove 913, the weighing sensor 10 is disposed in the sensor mounting groove 913, and the sensor fixing plate 12 is connected to the face case 91 to fix the weighing sensor 10 in the sensor mounting groove 913, the elastic member 2 is fixed to the sensor fixing plate 12, and the detection end of the weighing sensor 10 protrudes through the through hole of the sensor fixing plate 12 to be in contact with the pad 3 on the upper side of the elastically deformed end of the elastic member 2.

As shown in fig. 7-9, the outer side surface of the bottom shell 92 is provided with a supporting leg limiting bump 921 at a position where the horizontal adjusting leg passes through the bottom shell 92, so as to limit the maximum retraction position of the screw 7 connected with the supporting leg 1.

As shown in fig. 7-9, a waterproof horn 13 connected with the control board 11 is arranged in the bottom shell 91, the weight value of the displayed weighing object is broadcasted in real time through the waterproof horn 13, and after the bluetooth device is connected, the electronic scale can transmit the weight value to the connected electronic device in real time.

As shown in fig. 8-9, a sealing ring 12 is arranged between the open end of the control panel groove 911 and the inner side surface of the bottom shell 92, the weighing sensor 10 is arranged on the inner side of the surface shell 91, and the elastic piece 2 is fixed on the surface shell 91, so that the waterproof protection function of the control panel 11 is realized, and the user is not afraid of rain water drenching in the use or carrying process.

As shown in fig. 6, at least one handle through hole 13 is arranged on the scale body 9, so that the portable movement is facilitated.

The foregoing description of the preferred embodiments of the present utility model should not be construed as limiting the scope of the utility model, but rather should be understood to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model as defined by the following description and drawings or any application directly or indirectly to other relevant art(s).

Claims (10)

1. A horizontal adjustment foot structure, characterized in that: including supporting legs (1) and elastic component (2), elastic deformation end upside of elastic component (2) is equipped with gasket (3), elastic deformation end downside of elastic component (2) is equipped with passes power piece (4), pass power piece (4), elastic deformation end and gasket (3) between connect through screw (5), pass power piece (4) bottom surface and be equipped with power piece shrinkage pool (41), it has nut (6) to pass power piece shrinkage pool (41) are embedded, supporting legs (1) top is connected with screw rod (7) with nut (6) threaded connection.

2. A leveling foot structure in accordance with claim 1 wherein: the elastic piece (2) comprises an annular base (21), a deformation connecting portion (22) is arranged in the annular base (21), a plurality of elastic arms (23) are connected between the inner side face of the annular base (21) and the outer side face of the deformation connecting portion (22), the gasket (3) is arranged on the upper side face of the deformation connecting portion (22), the force transmission piece (4) is arranged on the lower side face of the deformation connecting portion (22), and the screw (5) is fixedly connected with the gasket (3), the deformation connecting portion (22) and the force transmission piece (4).

3. A leveling foot structure in accordance with claim 2 wherein: the upper side surface of the deformation connecting part (22) is provided with a connecting part groove (221), and the gasket (3) is arranged in the connecting part groove (221).

4. A leveling foot structure in accordance with claim 2 wherein: the outer side surface of the annular base (21) is provided with a plurality of connecting convex blocks (24), and convex block through holes (241) are formed in the connecting convex blocks (24).

5. A leveling foot structure in accordance with claim 2 wherein: an annular positioning lug (411) is arranged on the inner side surface of the concave hole (41) of the force transmission piece, and an annular positioning groove (61) matched with the annular positioning lug (411) is arranged on the outer side surface of the nut (6).

6. A leveling foot structure in accordance with claim 5 wherein: the bottom surface of the force transmission piece (4) is provided with a force transmission piece convex column (42), and a force transmission piece concave hole (41) is arranged on the bottom surface of the force transmission piece convex column (42).

7. A leveling foot structure in accordance with claim 1 wherein: the bottom surface of the supporting leg (1) is provided with an anti-slip pad (8).

8. An electronic scale using the horizontally adjusting foot structure of any one of claims 1 to 7, characterized in that: the automatic weighing device comprises a scale body (9), wherein a plurality of weighing sensors (10) are arranged in the scale body (9), an elastic piece (2) is fixed in the scale body (9), and the upper side surface of a gasket (3) arranged on the upper side of an elastic deformation end of the elastic piece (2) is contacted with the detection end of each weighing sensor (10).

9. The electronic scale of claim 8, wherein: the balance body (9) comprises a surface shell (91) and a bottom shell (92), a control board groove (911) is formed in the inner side of the surface shell (91), a control board (11) which is connected with a weighing sensor (10) and used for calculating and displaying weighing data is arranged in the control board groove (911), a sealing ring (12) is arranged between the opening end of the control board groove (911) and the inner side surface of the bottom shell (92), the weighing sensor (10) is arranged on the inner side of the surface shell (91), and an elastic piece (2) is fixed on the surface shell (91).

10. The electronic scale of claim 8, wherein: at least one handle through hole (13) is arranged on the balance body (9).