CN217550019U - Supporting device for powder equipment - Google Patents

Abstract

The utility model provides a strutting arrangement for be used for powder equipment, include the work unit and be used for supporting the support frame of work unit, be provided with weighing sensor between work unit and the support frame, the connecting block that the work unit lateral wall was provided with, the connecting block is located the support frame top, weighing sensor is located between connecting block and the support frame, weighing sensor passes through retaining member I and fixes with connecting block, support frame locking respectively. The utility model discloses have the weight of material in acquireing the work unit to acquire the material volume that needs to increase, make equipment work in the optimal state of needs, improve powder equipment work efficiency, product quality's effect.

Description

Supporting device for powder equipment

Technical Field

The utility model relates to a powder processing equipment field especially relates to a strutting arrangement for be used for powder equipment.

Background

At present, powder processing equipment such as an air flow mill, a powder classifier and the like relates to feeding of materials to a working unit (a crushing and classifying unit, a classifying unit and the like), and the quantity of the materials in the working unit is closely related to the processing efficiency and the product quality, so that quantitative indexes in the working unit are the key of the processing efficiency and the product quality of the powder processing equipment.

The existing powder equipment adopts a vibrating feeder, a screw feeder and the like for feeding, when in processing, the amount of materials in the working unit can not be determined, accurate instant quantization indexes are not available, the feeding amount required by the working unit can not be adjusted timely and accurately, and the product quality and the equipment working efficiency are influenced.

SUMMERY OF THE UTILITY MODEL

To exist not enough among the prior art, the utility model provides a strutting arrangement for powder equipment, it has solved the unable accurate material volume that acquires in the work unit of powder equipment that exists among the prior art, does not have accurate instant quantization index, and the feed volume that can not be timely, the accurate adjustment work unit needs influences product quality and equipment work efficiency's problem.

According to the utility model discloses an embodiment, a strutting arrangement for be used for powder equipment, include the work unit and be used for supporting the support frame of work unit, be provided with weighing sensor between work unit and the support frame, the connecting block that the work unit lateral wall was provided with, the connecting block is located the support frame top, weighing sensor is located between connecting block and the support frame, weighing sensor passes through retaining member I and fixes with connecting block, support frame locking respectively.

Further, the support frame evenly is provided with a plurality ofly around the unit of work, the connecting block is provided with a plurality ofly around the unit of work lateral wall, a plurality of support frames and connecting block one-to-one, all are provided with weighing sensor between each support frame and the connecting block.

Furthermore, the support frame still includes the backup pad that is located the work cell bottom and is located the telescopic machanism of backup pad bottom, telescopic machanism is used for controlling the lift of backup pad.

Further, the backup pad cross-section is the rectangle, telescopic machanism includes first telescopic link, first branch and first guide bar, first telescopic link is located backup pad geometric center, first guide bar has a plurality ofly around first telescopic link evenly distributed, first telescopic link passes through first branch fixed connection with first guide bar.

Further, the backup pad cross-section is trapezoidal, telescopic machanism includes the flexible subassembly of two sets of symmetry settings that the bisymmetry set up, flexible subassembly includes second telescopic link, second branch and second guide bar, the second telescopic link passes through second branch fixed connection with the second guide bar.

Further, first guide bar and second guide bar all include bracing piece I and slide the bracing piece II that sets up in bracing piece I, be equipped with retaining member II between bracing piece I and the bracing piece II, first via hole, the second via hole that supplies retaining member II to pass through are seted up respectively to bracing piece I, bracing piece II, retaining member II passes second via hole, first via hole in proper order and forms the locking fixedly to bracing piece I and bracing piece II.

Furthermore, the support frame still includes the mount table, telescopic machanism keeps away from the one end fixed connection of backup pad on the mount table.

The technical principle of the utility model is that: the weighing sensor is arranged between the working unit and the supporting frame, so that the weight of materials in the working unit can be detected, and the weight signal of the weighing sensor is used for determining the amount of the materials to be added in the working unit, so that the equipment works in the required optimal state.

Compared with the prior art, the utility model discloses following beneficial effect has: the weight of the materials in the working unit is obtained by arranging the weighing sensor between the working unit and the supporting frame, so that the amount of the materials to be added is obtained, the equipment works in a required optimal state, the working efficiency of the equipment is ensured, and the product quality is improved.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a second embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a third embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a fourth embodiment of the present invention.

Fig. 5 is a top view of a telescoping mechanism according to a second embodiment of the present invention.

Fig. 6 is a schematic structural view of a first guide bar in a second embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a fourth middle telescopic assembly according to the present invention.

Fig. 8 is a top view of a telescopic mechanism in the fourth embodiment of the present invention.

In the drawings, wherein: 1. a working unit; 2. a support plate; 3. a weighing sensor; 4. a hose; 5. a locking member I; 6. a platform; 7. a first telescopic rod; 8. a first support bar; 9. a first guide bar; 91. a support rod I; 92. a support rod II; 93. a locking member II; 10. a cyclone collector; 11. a dust collector; 12. a feeder; 13. a storage bin; 14. a support frame; 15. an installation table; 16. connecting blocks; 17. a charging bucket; 18. a second telescopic rod; 19. a second support bar; 20. a second guide bar.

Detailed Description

The technical solution of the present invention will be further explained with reference to the accompanying drawings and embodiments.

Example one

As shown in fig. 1, the embodiment of the utility model provides a strutting arrangement for powder equipment, include work unit 1 and be used for supporting work unit 1's support frame 14, be provided with weighing sensor 3 between work unit 1 and the support frame 14, work unit 1 cross-section is the disc, the position welding that work unit 1 lateral wall is close to the bottom has connecting block 16, connecting block 16 is located support frame 14 top, weighing sensor 3 is located between connecting block 16 and the support frame 14, weighing sensor 3 is fixed with connecting block 16, support frame 14 locking respectively through retaining member I5.

As shown in fig. 1, the three or four support frames 14 are uniformly arranged around the working unit 1, the three or four connecting blocks 16 are arranged around the side wall of the working unit 1 corresponding to the support frames 14, and a weighing sensor 3 is arranged between each support frame 14 and each connecting block 16.

In the above embodiment, the working unit 1 is a crushing and grading unit, the locking member I5 is a bolt, two ends of the weighing sensor 3 are respectively connected with the connecting block 16 and the supporting frame 14 through bolts, and hoses 4 are arranged between other elements connected with the crushing and grading unit and the crushing and grading unit to avoid affecting the weight of the crushing and grading unit, three or four weighing sensors 3 are arranged to enable the working unit 1 to be completely supported by the weighing sensors 3, so as to weigh the working unit 1, before the weighing sensors 3 are used, the weight of the crushing and grading unit and the weight of the hoses 4 relative to the crushing and grading unit need to be peeled, and the weight of materials in the working unit 1 is obtained by arranging the weighing sensors between the working unit 1 and the supporting frame 14, so as to obtain the amount of the materials to be increased, enable the equipment to work in the required optimal state, ensure the working efficiency of the equipment and improve the quality of the products.

During actual operation, the material of treating processing is held temporarily in feed bin 13, through the even feeding of vibrations batcher 12, flow in crushing classification unit through feeding hose 4, under the compressed gas effect, the material is broken and is graded, rethread discharge hose 4 gets into cyclone collector 10 and dust collector 11, weighing sensor 3 that sets up between crushing classification unit and support frame 14 obtains the weight signal who smashes classification unit, feed back to the treater, thereby acquire the material volume that needs to increase, make equipment work in the optimum state that needs, product quality and equipment production efficiency have been improved, this structure is applicable to the jet mill equipment.

Example two

As shown in fig. 2, the present embodiment is different from the first embodiment in that the supporting frame 14 further includes a supporting plate 2 located at the bottom of the working unit and a telescopic mechanism located at the bottom of the supporting plate 2, and the telescopic mechanism is used for controlling the lifting of the supporting plate 2.

As shown in fig. 2 and 5, the cross section of the supporting plate 2 is rectangular, the telescopic mechanism comprises a first telescopic rod 7, a first supporting rod 8 and a first guide rod 9, the first telescopic rod 7 is located at the geometric center of the supporting plate 2, the first guide rod 9 is uniformly distributed around the first telescopic rod 7, the first telescopic rod 7 is fixedly connected with the first guide rod 9 through the first supporting rod 8, and the first telescopic rod 7 is an electric cylinder.

As shown in fig. 6, first guide bar 9 includes bracing piece I91 and the bracing piece II92 of slip setting in bracing piece I91, be equipped with retaining member II93 between bracing piece I91 and the bracing piece II92, bracing piece I91, bracing piece II92 set up the first via hole, the second via hole that supply retaining member II93 to pass through respectively, retaining member II93 passes through the second via hole in proper order, first via hole forms locking fixed to bracing piece I91 and bracing piece II92, the vertical direction interval of bracing piece I91 is equipped with two first via holes, retaining member II93 is the bolt, when work unit 1 is in operating condition, the bolt passes the first via hole that is located the top and forms locking fixed to bracing piece I91 and bracing piece II92, and backup pad 2 and work unit 1 bottom surface contactless this moment, when work unit 1 needs to support, loosen retaining member II93, the electric cylinder drives bracing piece I91 through first branch 8 and rises to the corresponding position, retaining member II93 passes the first via hole that is located the below and forms locking fixed to bracing piece I91 and bracing piece II92, and first guide bar 9 also can play the supporting role to bracing piece 2 this moment.

As shown in fig. 2, the supporting frame 14 further includes an installation platform 15, one end of the telescopic mechanism far away from the supporting plate 2 is fixedly connected with the installation platform 15, and the installation platform 15 is arranged to enable the supporting frame 14 and the telescopic mechanism to be kept horizontal.

In the above embodiment, at ordinary times, the telescopic mechanism controls the support plate 2 to descend so that the support plate 2 does not contact with the bottom surface of the working unit 1, and at this time, the working unit 1 is completely supported by the weighing sensor 3; the supporting plate 2 is controlled to ascend through the telescopic mechanism, the supporting plate 2 can be used for supporting the working unit 1 independently, the weighing sensor 3 can be installed, tested, maintained or replaced at the moment, and the structure is suitable for airflow mill equipment.

EXAMPLE III

As shown in fig. 3, the present embodiment is different from the first embodiment in that the cross section of the working unit 1 is conical, and a connecting block 16 is welded at the middle position of the side wall of the working unit 1.

In the above embodiment, the working unit 1 is a grading unit, the material to be processed is temporarily stored in the storage bin 13, the material to be processed passes through the screw feeder 12, the hose 4 and enters the grading unit, a part of the material enters the charging basket 17 through the hose 4, a part of the material enters the subsequent devices such as the cyclone collector 10 through the hose 4, the grading unit is connected with the charging basket 17 through the hose 4, the charging basket 17 is placed on the platform 6, the weighing sensor 3 arranged between the grading unit and the support frame 14 obtains a weight signal of the grading unit and feeds the weight signal back to the processor, so that the material quantity required to be increased is obtained, the device is enabled to work in a required optimal state, the grading quality and the grading efficiency are ensured, and the structure is suitable for powder grader devices.

Example four

As shown in fig. 4, the present embodiment is different from the third embodiment in that the supporting frame 14 further includes a supporting plate 2 located at the bottom of the working unit 1 and a telescopic mechanism located at the bottom of the supporting plate 2, and the telescopic mechanism is used for controlling the lifting of the supporting plate 2.

As shown in fig. 4, 7 and 8, the cross section of the supporting plate 2 is trapezoidal, the telescopic mechanism comprises two symmetrically arranged telescopic assemblies, each telescopic assembly comprises a second telescopic rod 18, a second support rod 19 and a second guide rod 20, the second telescopic rods 18 and the second guide rods 20 are fixedly connected through the second support rods 19, the second telescopic rods 18 are electric cylinders, the supporting plate 2 is in a circular truncated cone shape corresponding to the working unit 1 and presents a shape wrapping the working unit 1, and the second guide rods 20 are identical to the first guide rods 9 in structure.

As shown in fig. 4, the supporting frame 14 further includes a mounting table 15, one end of the telescopic mechanism far away from the supporting plate 2 is fixedly connected with the mounting table 15, a hole for the feeding barrel 17 and the platform 6 to pass through is formed in the middle of the mounting table 15, and the supporting frame 14 and the telescopic mechanism can be kept horizontal by the aid of the mounting table 15.

In the above embodiment, when the working unit 1 works, the supporting plate 2 is controlled to descend by the telescopic mechanism so that the supporting plate 2 is not in contact with the bottom of the working unit 1, and at this time, the working unit 1 is completely supported by the weighing sensor 3; the supporting plate 2 is controlled to ascend through the telescopic mechanism, the working unit 1 can be supported by the supporting plate 2 independently, the weighing sensor 3 can be installed, tested, maintained or replaced at the moment, and the structure is suitable for powder classifier equipment.

Finally, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the present invention can be modified or replaced by other means without departing from the spirit and scope of the present invention, which should be construed as limited only by the appended claims.

Claims (6)

1. The utility model provides a strutting arrangement for be used for powder equipment which characterized in that: including work unit (1) and be used for supporting support frame (14) of work unit (1), be provided with weighing sensor (3) between work unit (1) and support frame (14), work unit (1) lateral wall is provided with connecting block (16), connecting block (16) are located support frame (14) top, weighing sensor (3) set up between connecting block (16) and support frame (14), weighing sensor (3) are fixed with connecting block (16), support frame (14) locking respectively through retaining member I (5).

2. The supporting device for powder equipment according to claim 1, wherein: support frame (14) evenly are provided with a plurality ofly around work unit (1), connecting block (16) are provided with a plurality ofly around work unit (1) lateral wall, a plurality of support frames (14) and connecting block (16) one-to-one, all are provided with weighing sensor (3) between each support frame (14) and the connecting block.

3. The supporting device for powder equipment according to claim 1, wherein: the supporting frame (14) further comprises a supporting plate (2) located at the bottom of the working unit (1) and a telescopic mechanism located at the bottom of the supporting plate (2), and the telescopic mechanism is used for controlling the supporting plate (2) to lift.

4. The supporting device for powder equipment as claimed in claim 3, wherein: the cross section of the supporting plate (2) is rectangular, the telescopic mechanism comprises a first telescopic rod (7), a first supporting rod (8) and a first guide rod (9), the first telescopic rod (7) is located at the geometric center of the supporting plate (2), the first guide rods (9) are uniformly distributed around the first telescopic rod (7), and the first telescopic rod (7) is fixedly connected with the first guide rod (9) through the first supporting rod (8); or the cross section of the support plate (2) is trapezoidal, the telescopic mechanism comprises telescopic assemblies which are symmetrically arranged, each telescopic assembly comprises a second telescopic rod (18), a second support rod (19) and a second guide rod (20), and the second telescopic rods (18) and the second guide rods (20) are fixedly connected through the second support rods (19).

5. The supporting device for powder equipment as claimed in claim 4, wherein: first guide bar (9) and second guide bar (20) all include bracing piece I (91) and slide the bracing piece II (92) that sets up in bracing piece I (91), be equipped with retaining member II (93) between bracing piece I (91) and bracing piece II (92), first via hole, the second via hole that supplies retaining member II (93) to pass through are seted up respectively to bracing piece I (91), bracing piece II (92), retaining member II (93) pass through second via hole, first via hole in proper order and form locking fixed to bracing piece I (91) and bracing piece II (92).

6. The supporting device for powder equipment as claimed in claim 3, wherein: the support frame (14) further comprises an installation table (15), and one end, far away from the support plate (2), of the telescopic mechanism is fixedly connected to the installation table (15).

Images