CN216410385U - Hanging basket type belt weigher calibration device - Google Patents

Abstract

The utility model relates to a calibration device of a hanging basket type belt weigher. Comprises a lifting mechanism, a rolling code component and a bracket; the lifting mechanism and the rolling code assembly are arranged on the bracket, and the bracket supports the rolling code in the rolling code assembly above the belt; the lifting mechanism is used for driving the rolling code assembly to lift so as to pack up the rolling code or place the rolling code on the belt weigher; the rolling code component comprises one or more rolling codes; roll sign indicating number both sides and be provided with the roller, direction spacing part is provided with the stroke groove, and the roller tip is installed in direction spacing part's stroke inslot, and stroke groove bottom is provided with stop gear for prevent that the roller tip from dropping from the stroke groove, and be used for promoting under the roll sign indicating number subassembly lifts the state and roll the sign indicating number. When the belt scale is calibrated, the roll shaft rises along the stroke groove relative to the side plate to leave the limiting mechanism at the bottom end of the stroke groove, and the rolling weight is completely supported by the belt without the action of external force, so that the calibration precision is improved.

Description

Hanging basket type belt weigher calibration device

Technical Field

The utility model belongs to the technical field of metering and inspection automation, and particularly relates to a calibration device of a hanging basket type belt scale.

Background

The electronic belt scale is a common metering device, and the accuracy of the electronic belt scale needs to be calibrated regularly. For the calibration of the electronic belt scale, a calibrator performs calibration work by using real object calibration or simulated real object calibration on site, and because the real object calibration process is complicated and the cost is high, the calibration is generally performed by using simulated real objects such as chain codes, bar codes or weights.

The chain code checking is that in the no-load operation of the belt conveyer, the electronic belt scale is firstly zeroed, then the chain code with standard weight is placed on the running conveyer belt, the material state is dynamically simulated, the weight is transferred to the weighing sensor through the scale body, and the instantaneous weight and cumulant are displayed through the calculation of the belt scale instrument. And comparing the accumulated amount of the weighing instrument with the reference value, and determining whether the actual error of the electronic belt scale is within the required range or not so as to verify the precision of the electronic belt scale by debugging.

In the chain sign indicating number check-up, the chain sign indicating number is itself heavier, and it is fixed to need a large amount of manpowers to carry the weighing range section to the belt weigher during the application, should not realize unmanned demarcation. And the structure of chain code causes itself easy bending to shorten, and the weight of per meter is inaccurate, receives the influence of belt off tracking easily, influences the check-up precision. In addition, the winding and unwinding of the automatic chain code are controlled by a winch, but the problem that the steel wire rope is dislocated and knotted due to groove separation is easily caused by the adoption of the winch, the fault is not easy to eliminate, and the occupied space of a support of the collecting device is large.

In practice, a cyclic chain code checking mode is adopted, although the operation is simple and convenient, the structure is complex, the weight is influenced by the traction chain, gravity cannot completely act on the belt, and the calibration precision is influenced.

Disclosure of Invention

In order to solve the technical defects, the utility model provides a calibration device of a hanging basket type belt scale.

The technical scheme for solving the technical problems is as follows: a calibration device of a hanging basket type belt scale comprises a lifting mechanism, a rolling code assembly and a bracket; the lifting mechanism and the rolling code assembly are arranged on the bracket, and the bracket supports the rolling code in the rolling code assembly above the belt; the lifting mechanism is used for driving the rolling code assembly to lift so as to pack up the rolling code or place the rolling code on the belt weigher.

Furthermore, the calibration device of the hanging basket type belt scale further comprises an outer cover, wherein the outer cover is arranged outside the rolling code assembly and the support or is integrated with the support, and the functions of dust prevention and protection are achieved.

Further, elevating system includes power part, and power part passes through adapting unit and drives and roll the lifting of sign indicating number subassembly.

Furthermore, the lifting mechanism also comprises a guide part, and the guide part provides a stroke track for the lifting of the rolling code assembly; the connecting part is a connecting hanging plate which is used for connecting the rolling code assembly.

Further, the power component comprises a motor and a lifting shaft, the motor is arranged on the bracket, and the lower end of the lifting shaft is connected with the connecting component; the motor drives the lifting shaft to move up and down, the lifting shaft drives the connecting component to move up and down, the lifting shaft is externally provided with or not provided with a lifting shaft sleeve, and the lifting shaft sleeve is arranged on the support.

Further, the guide part comprises a guide shaft sleeve and a guide shaft, the guide shaft sleeve is installed on the support, the lower end of the guide shaft is connected with the connecting hanging plate, the guide shaft sleeve is sleeved on the guide shaft, and when the motor drives the connecting hanging plate to move up and down, the guide shaft moves up and down in the guide shaft sleeve under the limit of the guide shaft sleeve.

Further, the rolling code component comprises one or more rolling codes; side plates are arranged on two sides of the rolling code, guide limiting parts are arranged on the side plates, roller shafts are arranged on two sides of the rolling code, the guide limiting parts are provided with stroke grooves, the end parts of the roller shafts are installed in the stroke grooves of the guide limiting parts, and limiting mechanisms are arranged at the bottom ends of the stroke grooves and used for preventing the end parts of the roller shafts from falling out of the stroke grooves and lifting the rolling code in a lifting state of the rolling code assembly; the two side plates are connected with a lifting mechanism.

Further, the guide limiting part is composed of linear guide pieces which are arranged in bilateral symmetry, the linear guide pieces are fixed on the side plates, and a stroke groove for the rolling code roll shaft to move up and down is formed between the two linear guide pieces; the limiting mechanism at the bottom end of the travel groove is formed by inwards extending the lower end parts of the two linear guide pieces.

Further, the two linear guide members extend inwards to form a closed structure, and the closed structure is a limiting mechanism.

Furthermore, the lower end parts of the two linear guide parts extend inwards to be not closed, an opening is reserved, the opening is smaller than the diameter of the end part of the roller shaft of the roller code or smaller than the diameter of a bearing installed at the end part of the roller shaft, and the opening formed by the inward extension and the non-closing of the lower end parts of the two linear guide parts is the limiting mechanism.

Further, the end portions of the two linear guide members extending inward from the lower ends thereof have a certain curvature or an inclined surface, the upper openings formed at the left and right end portions are larger than the diameter of the end portions of the roller shaft or larger than the diameter of the bearings mounted at the end portions of the roller shaft, and the lower openings formed at the left and right end portions are smaller than the diameter of the end portions of the roller shaft or smaller than the diameter of the bearings mounted at the end portions of the roller shaft.

Further, the bearing of roller tip suit is self-lubricating bearing, and self-lubricating bearing installs in the stroke inslot.

Further, the bearing includes a small diameter section and a large diameter section; a groove is formed between the linear guide piece and the side plate, and the width of the groove between the two linear guide pieces is matched with the diameter of the large-diameter section of the bearing; the width of the part, far away from the side plate, of the stroke groove is matched with the diameter of the small-diameter section of the bearing.

Further, the roll shafts on the two sides of the rolling code comprise a small-diameter section and a large-diameter section, a groove is formed between the linear guide piece and the side plate, and the width of the groove between the two linear guide pieces is matched with the diameter of the large-diameter section of the roll shaft; the width of the part, far away from the side plate, of the stroke groove is matched with the diameter of the small-diameter section of the roll shaft.

Furthermore, the rolling code assembly comprises two or more rolling codes, side plates of the rolling codes are arranged on the connecting hanging plate, and the side plates positioned on the same side of the rolling codes are connected through longitudinal edge strips.

Further, the longitudinal edge strips are connected with the side plates through carriage bolts, and the mounting position of the carriage bolts is located near the top end of the stroke groove on each side plate; the side plates of each rolling code positioned at two sides are connected and fixed by a transverse connecting plate.

Furthermore, the rolling code component is movably connected with the connecting hanging plate through a bolt.

Compared with the prior art, the utility model has the remarkable advantages that:

1. in the utility model, the rolling codes used as the simulation calibration objects are collected and released in a lifting mode, and the rolling codes are lifted and collected above the belt weighers in a non-working state, so that compared with the prior art, the full automation is realized, the simulation calibration objects do not need to be manually carried or adjusted and placed on the belt conveyor, and the collection space of the rolling codes is saved;

2. the angle between the hanging basket component and the belt can be adjusted according to the actual angle of the belt, and the gravity of the rolling weight always acts on the surface of the belt in a mode of being perpendicular to the center of the ground, so that the calibration method is suitable for calibrating different angles of the electronic belt scale, and the calibration precision is high;

3. when the belt scale is calibrated, the roll shaft rises along the stroke groove relative to the side plate to leave the limiting mechanism at the bottom end of the stroke groove, the weight of the rolling code is completely supported by the belt, the roll shaft self-lubricating bearing ensures that the rolling code slides freely on the belt, the roll shaft is free from the action of external force, and the calibration precision is improved.

Drawings

FIG. 1 is a schematic overall view of the present invention, including a front, top, and side view;

FIG. 2 is a schematic view of the lift mechanism of the present invention;

FIG. 3 is a schematic view of a rolling code assembly, including a front view and a side view;

FIG. 4 is a schematic view of a rolling code, including a front view and a side view;

FIG. 5 is a schematic view of a guide and stop member, including a front view and a top view;

FIG. 6 is a schematic view of a linear guide;

FIG. 7 is a schematic view of the linear guide in cooperation with the side plate, including a front, top and side view;

FIG. 8 is a schematic view of a roller code with a self-lubricating bearing installed, including a front view and a side view;

FIG. 9 is a schematic view of the self-lubricating bearing in cooperation with a guide stop member, including a front view and a side view;

fig. 10 is a schematic diagram of a rolling code assembly including a plurality of rolling codes. Comprises a front view and a bottom view;

FIG. 11 is a perspective view of the bracket and cover;

fig. 12 is a front and side view of the bracket and cover.

In the figure, the lifting mechanism 1, the rolling code assembly 2, the bracket 3, the outer cover 4, the power part 11, the guide part 12, the connecting hanger plate 13, the motor 111, the lifting shaft 112, the lifting shaft sleeve 113, the guide shaft sleeve 121, the guide shaft 122, the rolling code 21, the side plate 22, the guide limit part 23, the roller shaft 211, the stroke groove 233, the limit mechanism 234, the linear guide 231, the linear guide 232, the self-lubricating bearing 212, the small diameter section 2121, the large diameter section 2122, the groove 222, the longitudinal edge strip 24, the carriage bolt 25, the transverse connecting plate 26 and the bolt 27.

Detailed Description

It is easily understood that various embodiments of the present invention can be conceived by those skilled in the art according to the technical solution of the present invention without changing the essential spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are merely illustrative of the technical aspects of the present invention, and should not be construed as all of the present invention or as limitations or limitations on the technical aspects of the present invention.

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the utility model, its application, or uses.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

With reference to fig. 1, the calibration device of the hanging basket type belt scale of the present invention comprises a lifting mechanism 1, a rolling code assembly 2, a bracket 3 and an outer cover 4; the lifting mechanism 1 and the rolling code assembly 2 are arranged on the bracket 3, and the rolling code 21 in the rolling code assembly 2 is used as a simulation object for calibrating the belt scale. Elevating system 1 is used for driving and rolls a yard subassembly 2 and goes up and down, and when needs demarcated the belt weigher, elevating system 1 will roll yard subassembly 2 and descend until will roll yard 21 and transfer to the belt weigher on. After the calibration is completed, the lifting mechanism 1 lifts the rolling code assembly 2, and the basket code assembly 2 is folded, so that the normal work of the belt scale is not influenced. The bracket 3 supports the rolling codes 21 in the rolling code assembly 2 above the weighing section of the belt scale. The outer cover 4 is arranged outside the rolling code assembly 2 and the bracket 3 or is integrated with the bracket 3, and mainly plays a role in dust prevention and protection.

Referring to fig. 2, the lifting mechanism 1 includes a power member 11, a guide member 12, and a connection hanger plate 13. The connecting hanging plate 13 is used for connecting the rolling code assembly 2.

In one embodiment, the power unit 11 includes a motor 111 and a lifting shaft 112, the motor 111 is mounted on the bracket 3 through a motor mounting seat, and the lower end of the lifting shaft 112 is connected to the connecting hanger plate 13. The motor 111 drives the lifting shaft 112 to move up and down, and the lifting shaft 112 drives the connecting hanging plate 13 to move up and down. The elevating shaft 112 is externally provided with an elevating shaft sleeve 113. The lifting shaft sleeve 113 is arranged on the support 3, and the lifting shaft sleeve 113 can play a role in protection and can play a role in guiding and limiting.

In one embodiment, the guide member 12 includes a guide sleeve 121 and a guide shaft 122, the guide sleeve 121 is flange-mounted on the bracket 3, and the lower end of the guide shaft 122 is connected to the connection hanger plate 13. When the motor drives the connecting hanging plate 13 to move up and down, the guide shaft 122 moves up and down in the guide shaft sleeve under the limit of the guide shaft sleeve 121. Of course, the guide member may also take other embodiments, for example, using linear slides or the like.

Preferably, the guide shaft sleeve 121 and the lifting shaft sleeve 113 are provided therein with an upper limit mechanism and a lower limit mechanism, which limit the stroke of the guide shaft 122 and the lifting shaft 112 therein.

With reference to fig. 3, the rolling code assembly 2 includes one or more rolling codes 21, side plates 22 are disposed on two sides of the rolling codes 21, and guide limiting parts 23 are disposed on the side plates 22; as shown in fig. 4, the roll shafts 211 are provided on both sides of the round roller code 21 having a standard weight, the guide stopper member 23 is provided with the stroke groove 233, the roll shafts 211 on both sides of the roller code 21 are installed in the stroke groove 233 of the guide stopper member 23, and the roller code 21 can slide up and down along the stroke groove 233. The bottom end of the stroke groove 233 is provided with a limiting mechanism for preventing the rolling code 21 from falling from the stroke groove 233, and plays a role of lifting the rolling code 21 in a lifting state of the rolling code assembly 2. Specifically, the roller shafts 211 work together with the guide limiting part 23, when the rolling code assembly 2 is in a lifting state, that is, the rolling code 21 is not in contact with the belt scale, the roller shafts 211 on both sides of the rolling code 21 are positioned at the bottom of the guide limiting part 23, that is, at the limiting mechanism, and the roller shafts 211 are supported by the limiting mechanism so as to suspend the rolling code 211 in the air; when the rolling code assembly 2 descends to the working position, the rolling code 211 is in contact with the belt and is finally supported by the belt, the roller shafts 211 on the two sides of the rolling code 21 are lifted relative to the guide limiting part 23 along the stroke grooves 233 in the guide limiting part 23, the roller shafts 211 are not in contact with the limiting mechanism at the bottom end of the guide limiting part 23 any more, at this time, the guide limiting part 23 does not generate upward lifting force on the rolling code 21, and the rolling code 21 is freely placed on the belt. The size of the rolling code 21 depends on the size of the nominal value, and the overall weight and number depend on the difference between the nominal value and the check length.

Referring to fig. 5, 6 and 7, the guide stopper 23 is formed of two linear guides 231 and 232 symmetrically disposed in the left-right direction, the two linear guides 231 and 232 symmetrically disposed are fixed to the side plate 22, and a stroke groove 233 for moving the roller shaft 211 of the roller code 21 up and down is formed between the two linear guides 231 and 232. The limiting mechanism at the bottom end of the travel slot 233 is formed by extending inward the lower end 234 of the two linear guides 231, 232.

Although not shown, the lower ends of the two linear guides 231, 232 extend inward to the bottom of the closed travel slot 233, and the closed structure formed by the inward extension of the lower ends 234 of the two linear guides 231, 232 is the limiting mechanism. Further, the lower ends 234 of the two linear guides 231, 232 extend inward and are connected together to form an arc structure, which is a limiting mechanism.

When the bottom end of the stroke groove 233 is closed, the overall length of the guide stopper member 23 becomes longer. When the rolling codes fall on the belt surface for calibration, the distance from the lowest end of the guide limiting component 23 to the belt surface is relatively reduced, the belt shakes during operation, and the lowest end of the guide limiting component 23 is likely to touch the belt surface to influence the calibration precision. As a modified embodiment, referring to fig. 5, 6 and 7, the lower ends 234 of the two linear guides 231, 232 extend inward but are not closed, leaving an opening. The ends 234 of the two linear guides 231, 232 extending inward at their lower ends have a curvature or slope 235 with an upper opening between the ends that is larger than the lower opening of the ends, the upper opening being larger than the diameter of the roller shaft 211 and the lower opening between the ends being smaller than the diameter of the roller shaft 211, thereby serving to increase the stroke of the stroke groove 233. I.e. the lower inwardly extending end 234 of the two linear guides 231, 232 constitutes the stop mechanism, but the stop mechanism is not closed. Under the condition that the diameter of the rolling code 21 is fixed, the descending height of the side plate 22 and the guide limiting part 23 can be reduced, namely the height of the guide limiting part 23 can be increased to some extent, so that the side plate 22 or the guide limiting part 23 is prevented from contacting a belt to influence the calibration precision.

Referring to fig. 8 and 9, as an embodiment, a self-lubricating bearing 212 is sleeved on the roller shaft 211 on both sides of the roller code 21, and the self-lubricating bearing 212 includes a small-diameter section 2121 and a large-diameter section 2122. A groove 222 is further formed between the linear guides 231, 232 and the side plate 22, i.e., where the stroke groove 233 is close to the side plate 22, has a large width so as to be engaged with the large-diameter section 2122 of the self-lubricating bearing 212; the portion of the stroke groove 233 remote from the side plate 22 is smaller in width so as to fit with the small diameter section 2121 of the self-lubricating bearing 212. Thus, the self-lubricating bearing 212 is axially fitted in the stroke groove 233, and the roller shaft 211 is further prevented from coming off the stroke groove 233. In the case of installing the self-lubricating bearing 212, the end portions 234 of the two linear guides 231, 232 extending inward from the lower ends thereof have a curvature or inclined surface 235, the upper end openings of which are larger than the diameter of the self-lubricating bearing 212 and the lower end openings of which are smaller than the diameter of the self-lubricating bearing 212.

As an alternative embodiment, the roller shafts 211 at both sides of the roller code 21 include a small diameter section and a large diameter section. A groove 222 is further formed between the linear guides 231 and 232 and the side plate 22, i.e., a stroke groove 233 having a large width near the side plate 22 to be engaged with a large diameter section of the roller shaft; the portion of the travel slot remote from the side plate 22 is of lesser width to engage the smaller diameter section of the roller shaft. The roll shaft is clamped in the stroke groove in the axial direction.

Two side plates 22 are mounted on the connecting hanger plate 3 to connect the lifting mechanism 1 with the roller code assembly 2.

Referring to fig. 10, as an embodiment, the roller code assembly 2 includes two or more roller codes 21, and the side plates 22 of the roller codes 21 are sequentially installed on the connecting hanger plate 13 at a predetermined distance from each other. The side panels 22 on the same side of the roll codes 21 are connected by longitudinal strips 24 so that two or more roll codes 21 are connected by the longitudinal strips 24 to form a coordinated whole. The longitudinal edge strips 24 are connected with the side plates 22 through carriage bolts 25, and on each side plate 22, the mounting positions of the carriage bolts 25 are located near the top end of the stroke grooves 233, so that the top end limiting effect of the stroke grooves 233 can be achieved, the roller shafts 211 are prevented from falling out of the top ends of the stroke grooves 233, and the tops of the rolling codes 21 are prevented from abutting against the connecting hanger plate 13. The side plates 22 of each rolling code 21 on both sides can be further connected and fixed by a transverse connecting plate 26 for enhancing the stability of the whole frame.

The bracket 3 and the outer cover 4 are directly placed on the bracket of the electronic belt scale and positioned above the weighing section of the belt scale, and the width of the bracket is adjusted according to the bandwidth of the belt scale; the shaft sleeve flange of the guide part 12 and the motor base of the elevator are connected with the top plate of the support, and the connecting hanging plate 13 and the rolling code assembly 2 in the lifting mechanism 1 are integrally suspended on the inner side of the support through the motor and the lifting shaft in the lifting mechanism 1, so that the support space of the existing automatic chain code collecting device is saved, and the installation space is saved.

Before the calibration device of the hanging basket type belt scale works, the rolling code component 2 is hung on the inner side of the support by the support 3 and is positioned above the weighing end of the belt scale. Under the idle state, roll yard subassembly 2 and be packed up by elevating system 1, lift axle is promoted to the highest position by the motor promptly, rolls yard subassembly 2 and places in support 3 roof below, belt top, and it is enough in order not to influence the belt balance work to pack up the height. At this time, the roller shafts 211 on both sides of the roller code 21 are positioned at the bottom of the stroke groove 233 of the guide stopper member 23 and suspended in the air by the stopper mechanism 234 at the bottom of the stroke groove 233.

When the belt scale needs to be calibrated, the motor 111 starts to work, the lifting shaft 112 is lowered, the motor 111 drives the lifting shaft 112 to descend along the lifting shaft sleeve 113, and the guide shaft 122 also descends along the guide shaft sleeve 121. When the rolling weight 21 contacts the belt and the belt starts to support the weight of the rolling weight 21, the lifting shaft 112 is driven by the motor 111 to continuously descend, the connecting hanging plate 13 drives the two side plates 22 of the rolling weight 21 to continuously descend, and the rolling weight 21 and the side plates 22 generate relative displacement. Specifically, the side plate 22 continues to descend relative to the roller code 21 and the roller shaft 211, the roller shaft 211 rises relative to the side plate 22 along the stroke groove 233 to leave the limiting mechanism at the bottom end of the stroke groove 233, at this time, the weight of the roller code 21 is completely supported by the belt, the roller code 21 can be used as a simulated calibration object to calibrate the belt scale, and the weight of the roller code 21 is not interfered by other parts, so that the calibration precision is improved.

When the lifting mechanism 1 operates, the connecting hanging plate 13 drives the rolling code assembly 2 to operate up and down together, and the stroke, the upper limit and the lower limit of the lifting mechanism 1 are controlled by the controller. When the lifting mechanism 1 is limited at the upper part, namely in a receiving state, the rolling code assembly 2 is hung through the guide limiting part 23, and the rolling code 21 is suspended in the air, so that the normal operation of materials cannot be influenced; when the belt conveyor belt is positioned at the lower limit, namely in the calibration state, the rolling codes 21 are suspended in the guide limit part 23 and are not in contact with the limit mechanism 234, and the weight of the rolling codes 21 directly acts on the surface of the belt, so that the calibration of a material is simulated.

In the utility model, the lifting mechanism replaces the traditional winding machine collecting device, thereby avoiding the problem that the steel wire rope of the winding machine is dislocated and knotted when being taken off the groove. When the chain code steel wire rope traction device operates, the guide component is limited, and the problem that the traditional chain code steel wire rope traction device is prone to belt deviation is solved. The whole process of calibration and collection does not need manual carrying and adjustment, and calibration automation is realized.

In the utility model, the roller code 21 is large in diameter, the roller shaft is small in diameter, namely, in the rotation process, the roller code 21 is a large shaft, and the roller shaft 211 is a small shaft, so that the radial rotating force of the small shaft is increased, the roller code 21 can flexibly rotate, and the relative displacement with a belt is reduced. When the self-lubricating bearings are mounted on the roller shafts 211 at the two ends, the roller codes 21 are further ensured to freely slide on the belt, and the calibration precision is improved.

Referring to fig. 10, the rolling code assemblies 2 are connected to the connecting hanger plate 13 by bolts 27, and each rolling code assembly 2 is connected by a longitudinal edge strip 24. When the electronic belt scale is in a non-horizontal state, the bolt 26 for connecting the rolling code assembly 2 and the hanging plate 13 can be loosened, the falling angle of the rolling code assembly is automatically adjusted by utilizing the free falling body principle, and the gravity of the rolling code 21 acts on the belt surface in a mode of being perpendicular to the center of the ground all the time. Therefore, the calibration device is suitable for calibrating the electronic belt scale at different angles and has high calibration precision.

Although not all schematic diagrams are shown, in the present invention, the rolling codes 21 in the rolling code assembly can be set to be a single row of rolling codes, a double row of rolling codes or a plurality of rows of rolling codes according to specific calibration values, so as to perform linear multi-point calibration. When double row rolls the sign indicating number, and the connection hanger plate 13 has two rows of roll the sign indicating number along belt width direction, and the belt is vertical, and every row rolls the sign indicating number and includes one or more roll the sign indicating number 8.

In order to simulate the running state of a real object as much as possible, the detection weight should not be influenced by external force and directly act on the belt under an ideal condition. The utility model can reduce the influence of external force on the gravity of the detected heavy object as much as possible. The chain of traditional chain sign indicating number rolls the sign indicating number and is connected by chain sign indicating number board, when the calibration, receives the effect of belt operation traction force, and the chain sign indicating number is crooked easily, has reduced the original length of chain sign indicating number at weighing the frame to influence chain sign indicating number per meter weight. In the utility model, the rolling codes are arranged on the connecting hanging plate, so that the distance between the rolling codes cannot be changed. The utility model can also connect all rolling codes by using edge strips, further the rolling codes are integrated, the distance between the rolling codes is not changed, namely the total weight of the rolling codes in unit distance is not influenced, the error of the actual weight per meter of a calibration object on the belt is reduced, and the positioning precision is improved. The utility model can also adjust the basket code installation angle according to the belt conveyor installation angle, ensure that the gravity of the detected heavy object is not influenced by external force and points to the ground, and is suitable for calibrating the belt weigher with a certain inclination under the condition of ensuring the calibration precision.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.

It should be appreciated that in the foregoing description of exemplary embodiments of the utility model, various features of the utility model are sometimes described in a single embodiment or with reference to a single figure, for the purpose of streamlining the disclosure and aiding in the understanding of various aspects of the utility model by those skilled in the art. However, the present invention should not be construed such that the features included in the exemplary embodiments are all the essential technical features of the patent claims.

Claims (17)

1. A calibration device of a hanging basket type belt scale is characterized by comprising a lifting mechanism (1), a rolling code assembly (2) and a bracket (3); the lifting mechanism (1) and the rolling code assembly (2) are arranged on the bracket (3), and the bracket (3) supports the rolling code (21) in the rolling code assembly (2) above the belt; the lifting mechanism (1) is used for driving the rolling code assembly (2) to lift so as to pack up the rolling code (21) or place the rolling code (21) on the belt weigher.

2. The calibration device of the basket belt scale as claimed in claim 1, further comprising a cover (4), wherein the cover (4) is installed outside the rolling code assembly (2) and the bracket (3) or is integrated with the bracket (3).

3. The calibration device of the hanging basket type belt scale as claimed in claim 1, wherein the lifting mechanism (1) comprises a power component (11), and the power component (11) drives the rolling code component (2) to lift through a connecting component.

4. The calibration device of the hanging basket type belt scale as claimed in claim 3, wherein the lifting mechanism (1) further comprises a guide component (12), the guide component (12) provides a travel track for the rolling code component (2) to lift; the connecting part is a connecting hanging plate (13), and the connecting hanging plate (13) is used for connecting the rolling code assembly.

5. The calibration device of the hanging basket type belt scale as claimed in claim 3 or 4, wherein the power component (11) comprises a motor (111) and a lifting shaft (112), the motor (111) is mounted on the bracket (3), and the lower end of the lifting shaft (112) is connected with the connecting component; the motor (111) drives the lifting shaft (112) to move up and down, the lifting shaft (112) drives the connecting part to move up and down, the lifting shaft (112) is externally provided with or not provided with a lifting shaft sleeve (113), and the lifting shaft sleeve (113) is arranged on the support (3).

6. The calibration device of the hanging basket type belt scale as claimed in claim 4, wherein the guiding component (12) comprises a guiding shaft sleeve (121) and a guiding shaft (122), the guiding shaft sleeve (121) is installed on the bracket (3), the lower end of the guiding shaft (122) is connected with the connecting hanging plate (13), the guiding shaft sleeve (121) is sleeved on the guiding shaft (122), and when the motor drives the connecting hanging plate (13) to move up and down, the guiding shaft (122) moves up and down in the guiding shaft sleeve under the limit of the guiding shaft sleeve (121).

7. The calibration device of the hanging basket type belt scale as claimed in claim 1, wherein the rolling code assembly (2) comprises one or more rolling codes (21); side plates (22) are arranged on two sides of the rolling code (21), guide limiting parts (23) are arranged on the side plates (22), roller shafts (211) are arranged on two sides of the rolling code (21), stroke grooves (233) are formed in the guide limiting parts (23), the end parts of the roller shafts (211) are installed in the stroke grooves (233) of the guide limiting parts (23), and limiting mechanisms are arranged at the bottom ends of the stroke grooves (233) and used for preventing the end parts of the roller shafts (211) from falling out of the stroke grooves (233) and lifting the rolling code (21) in a lifting state of the rolling code assembly (2); the two side plates (22) are connected with the lifting mechanism (1).

8. The calibration device of the basket belt scale as claimed in claim 7, wherein the guide position limiting member (23) is composed of linear guides (231, 232) symmetrically arranged from side to side, the linear guides (231, 232) are fixed on the side plate (22), and a stroke groove (233) for the roller shaft (211) of the rolling weight (21) to move up and down is formed between the two linear guides (231, 232); the limiting mechanism at the bottom end of the travel groove (233) is formed by extending inward the lower end (234) of the two linear guide members (231, 232).

9. The calibration device of the hanging basket type belt scale as claimed in claim 8, wherein the lower end (234) of the two linear guides (231, 232) is extended inward to form a closed structure, and the closed structure is a limiting mechanism.

10. The calibration device of the hanging basket type belt scale as claimed in claim 8, wherein the lower end (234) of the two linear guides (231, 232) is not closed and extends inwards, leaving an opening, the opening is smaller than the diameter of the roller shaft end or the diameter of the bearing mounted on the roller shaft end, and the opening formed by the lower end (234) of the two linear guides (231, 232) extending inwards and not being closed is the limiting mechanism.

11. The calibration device of the basket belt scale as claimed in claim 10, wherein the lower inwardly extending end portions (234) of the two linear guides (231, 232) have a curvature or an inclined surface (235), the upper openings formed at the left and right end portions (234) are larger than the diameter of the end portions of the roller shaft or larger than the diameter of the bearings mounted at the end portions of the roller shaft, and the lower openings formed at the left and right end portions (234) are smaller than the diameter of the end portions of the roller shaft or smaller than the diameter of the bearings mounted at the end portions of the roller shaft.

12. The calibration device of the basket type belt scale according to any one of the claims 10 or 11, wherein the bearing sleeved on the end of the roll shaft is a self-lubricating bearing (212), and the self-lubricating bearing (212) is installed in the stroke slot (233).

13. The calibration device of the hanging basket belt scale as claimed in claim 12, wherein the bearing comprises a small diameter section (2121) and a large diameter section (2122); a groove (222) is further formed between the linear guide (231, 232) and the side plate (22), and the width of the groove (222) between the two linear guide (231, 232) is matched with the diameter of the large-diameter section (2122) of the bearing; the width of the part of the stroke groove (233) far away from the side plate (22) is matched with the diameter of the small-diameter section (2121) of the bearing.

14. The calibration device of the basket type belt scale as claimed in claim 7, wherein the roll shaft (211) at both sides of the roller (21) comprises a small diameter section and a large diameter section, a groove (222) is further formed between the linear guide members (231, 232) and the side plate (22), and the width of the groove (222) between the two linear guide members (231, 232) is adapted to the diameter of the large diameter section of the roll shaft (211); the width of the part of the stroke groove (233) far away from the side plate (22) is matched with the diameter of the small-diameter section of the roller shaft (211).

15. The calibration device of the basket type belt scale as claimed in claim 7, wherein the rolling code assembly (2) comprises two or more rolling codes (21), the side plate (22) of each rolling code (21) is installed on the connecting hanging plate (13), and the side plates (22) positioned at the same side of the rolling codes (21) are connected by a longitudinal edge strip (24).

16. The calibration device of the basket belt scale as claimed in claim 15, wherein the longitudinal edge strips (24) are connected to the side plates (22) by carriage bolts (25), and the carriage bolts (25) are mounted on each side plate (22) at positions near the top ends of the travel slots (233); the side plates (22) of each rolling code (21) positioned at two sides are connected and fixed by a transverse connecting plate (26).

17. The calibration device of the basket belt scale as claimed in claim 7, wherein the rolling code assembly (2) is movably connected with the connecting suspension plate (13) by a bolt (27).

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