CN220200591U - Discharging mechanism of particle hardness test sample tray - Google Patents

Abstract

The utility model discloses a discharging mechanism of a particle hardness test sample tray, which comprises a switching turntable, a tray, a feeding trough frame, a to-be-tested trough, a push plate, a driving motor, a toothed ring and a gear; the middle part of the switching turntable is movably connected with a detection platform of the automatic particle strength tester; the tray is nested and fixed at the edge position close to the switching turntable; a toothed ring is fixed on the bottom surface of the switching turntable; the feeding trough rack is arranged above the detection platform of the automatic particle strength tester in a crossing manner, a discharge hole at the bottom of the feeding trough rack corresponds to the edge position of the switching turntable, and the tray rotates to the lower part of the feeding trough rack along with the switching turntable; a feeding hole is formed in the front face of the feeding trough frame; a groove to be measured is fixed at the outer side of the feeding hole; a push plate is arranged in the groove to be tested; a driving motor is fixed at the back of the feeding trough frame; a gear is fixed at the driving end of the driving motor; the gear is meshed with the rack for transmission.

Description

Discharging mechanism of particle hardness test sample tray

Technical Field

The utility model relates to the technical field of feed testing equipment, in particular to a discharging mechanism of a particle hardness test sample tray.

Background

The hardness of the pellet feed is an important index for measuring the processing quality of the pellet feed, and refers to the resistance of the pellet feed to deformation caused by external pressure. The pellet hardness of the feed is generally detected using an automatic pellet strength tester; during each detection, the rod-shaped feed particles to be detected are manually placed in the detection tray, and the particle feed cannot be stably positioned during manual feeding because the detection point is positioned in the middle of the tray, and the hand needs to extend below the detection part of the equipment, so that the operation is very inconvenient; in addition, in the detection process, as the number of samples to be detected is large, if the samples are not classified in time, the result is inaccurate due to the fact that different sample values and parameters are mixed easily, the workload of staff is increased, and the working efficiency is low.

The utility model comprises the following steps:

according to the defects of the prior art, the utility model provides a discharging mechanism of a particle hardness test sample tray, through which rod-shaped feed particles are smoothly pushed into a detection part for operation by a discharging device through direct feeding from the rear of equipment.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the discharging mechanism of the granularity test sample tray comprises a switching turntable, a tray, a feeding trough rack, a trough to be tested, a push plate, a driving motor, a toothed ring and a gear; the middle part of the switching turntable is movably connected with a detection platform of the automatic particle strength tester; the tray is nested and fixed at the edge position close to the switching turntable; a toothed ring is fixed on the bottom surface of the switching turntable; the feeding trough rack is arranged above the detection platform of the automatic particle strength tester in a crossing manner, a discharge hole at the bottom of the feeding trough rack corresponds to the edge position of the switching turntable, and after the tray rotates below the feeding trough rack along with the switching turntable, the middle part of the tray corresponds to the discharge hole of the feeding trough rack; an arc-shaped guide chute is arranged in the middle of the feeding chute frame; a feeding hole is formed in the front face of the feeding trough frame; a groove to be measured is fixed at the outer side of the feeding hole; a push plate is arranged in the groove to be tested; a driving motor is fixed at the back of the feeding trough frame; a gear is fixed at the driving end of the driving motor; the gear is meshed with the rack for transmission.

Preferably, the push rod is fixed on the back of the push plate; the push rod penetrates out of the front surface of the groove to be measured; the pushing end of the push rod is fixed with a stop block.

Preferably, the driving motor is fixed on one side of the back of the upper trough frame through the surface of the fixing frame.

Preferably, the feeding trough frame is stuck with more than one detection mark at the lower position corresponding to the to-be-detected trough.

Preferably, the diameter of the toothed ring is smaller than the diameter of the switching turntable, and the toothed ring is hidden below the switching turntable.

Preferably, a universal ball for reducing friction is arranged below the switching turntable at a detection position corresponding to the particle detection device.

The utility model has the beneficial effects that:

the device puts the detection sample that awaits measuring into the groove that awaits measuring in proper order, and every detection sample corresponds a detection groove, once the push rod pushes, the push rod of pushing just represents that the detection sample of this mark has carried out the detection statistics. After waiting to detect the appearance and getting into the silo frame, get into the tray middle part along the baffle box, the carousel resets through driving motor and rotates the below that gets back to the granularity tester and be convenient for to the test of detecting the appearance, and artifical lofting is located the outside, and the operation is more convenient, and it is more convenient to count.

Description of the drawings:

in order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic diagram of the positional relationship of the present utility model.

Fig. 3 is a schematic diagram of a driving structure of the present utility model.

Fig. 4 is a schematic cross-sectional structure of the feeding trough rack of the present utility model.

In the figure, a switching turntable 1, a tray 2, a feeding groove frame 3, a discharge hole 3.1, a feeding hole 3.2, a guide groove 3.3, a groove to be tested 4, a push plate 5, a driving motor 6, a toothed ring 7, a gear 8, a push rod 9, a fixing frame 10, a universal ball 11, an automatic particle intensity tester 12 and a mark 13.

The specific embodiment is as follows:

as shown in the figure, the discharging mechanism of the granularity measurement sample disk mainly comprises a switching turntable 1, a tray 2, a feeding groove frame 3, a groove to be measured 4, a push plate 5, a driving motor 6, a toothed ring 7 and a gear 8; the middle part of the switching turntable 1 is movably connected with a detection platform of an automatic particle intensity analyzer 12, the automatic particle intensity analyzer 12 is an improvement on the basis of the existing detection equipment, and the model of the equipment is KQ-3. The tray 2 is nested and fixed at the edge position close to the switching turntable 1; the bottom surface of switching carousel 1 is fixed with ring gear 7, and ring gear 7 diameter is best to be less than switching carousel 1 diameter, and ring gear 7 hides in the below of switching carousel 1, can effectively protect transmission structure. The feeding trough frame 3 is arranged above a detection platform of the automatic particle strength tester 12 in a crossing manner, a discharge hole 3.1 at the bottom of the feeding trough frame 3 corresponds to the edge position of the switching turntable 1, and after the tray 2 rotates below the feeding trough frame 3 along with the switching turntable 1, the middle part of the tray 2 corresponds to the discharge hole 3.1 of the feeding trough frame 3; an arc-shaped guide chute 3.3 is arranged in the middle of the feeding chute frame 3. In order to reduce the stress of the pressure on the rotating structure during the detection of the turntable, a universal ball 11 for reducing friction is arranged below the switching turntable at a detection position corresponding to the automatic particle intensity measuring instrument 12.

As shown in the figure, a feeding hole 3.2 is formed in the front surface of the feeding trough frame 3; a groove 4 to be measured is fixed at the outer side of the feeding hole 3.2; a push plate 5 is arranged in the groove 4 to be measured, and a push rod 9 is fixed at the back of the push plate 5; the push rod 9 penetrates out of the front surface of the groove 4 to be tested; a stop block is fixed at the pushing end of the push rod 9. A driving motor 6 is fixed at the back of the feeding trough frame 3; a gear 8 is fixed at the driving end of the driving motor 6; the gear 8 is meshed with the rack for transmission, the rotation angle can be controlled to be 180 degrees, the stop position of the tray 2 is positioned below the discharge hole 3.1 or below the detection part of the granularity detector, and a groove for placing a detection sample is formed in the middle detection area of the tray 2. Specifically, the driving motor 6 fixes the driving motor 6 on the back side of the upper chute frame 3 through the surface of the fixing frame 10. In order to facilitate the confirmation of the number of samples to be detected and the numerical value marks 13 to be detected, more than one detection mark 13 is stuck at the lower position of the upper trough frame 3 corresponding to the trough 4 to be detected, and the detected numerical values after detection correspond to the marks 13 one by one. The above-mentioned fixing means, unless described separately, are welded or screwed by means of common techniques by those skilled in the art.

When the feeding device is used, 12 cases of particles to be detected are selected, each case of feed is placed in the groove 4 to be detected, when the feed needs to be detected, the corresponding push rod 9 is pushed in, the particles to be detected enter the feeding groove frame 3 and finally fall into the middle of the tray 2 through the discharge hole 3.1, and after each group of the particles to be detected is detected, the numerical value of the particles to be detected is recorded according to the corresponding number of the mark 13.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The discharging mechanism of the particle hardness test sample tray comprises a switching turntable, a tray, a feeding trough rack, a trough to be tested, a push plate, a driving motor, a toothed ring and a gear; the method is characterized in that: the middle part of the switching turntable is movably connected with a detection platform of the automatic particle strength tester; the tray is nested and fixed at the edge position close to the switching turntable; a toothed ring is fixed on the bottom surface of the switching turntable;

the feeding trough rack is arranged above the detection platform of the automatic particle strength tester in a crossing manner, a discharge hole at the bottom of the feeding trough rack corresponds to the edge position of the switching turntable, and after the tray rotates below the feeding trough rack along with the switching turntable, the middle part of the tray corresponds to the discharge hole of the feeding trough rack; an arc-shaped guide chute is arranged in the middle of the feeding chute frame; a feeding hole is formed in the front face of the feeding trough frame; a groove to be measured is fixed at the outer side of the feeding hole; a push plate is arranged in the groove to be tested; a driving motor is fixed at the back of the feeding trough frame; a gear is fixed at the driving end of the driving motor; the gear is meshed with the rack for transmission.

2. The discharge mechanism of a particle hardness test disc according to claim 1, wherein: a push rod is fixed at the back of the push plate; the push rod penetrates out of the front surface of the groove to be measured; the pushing end of the push rod is fixed with a stop block.

3. The discharge mechanism of a particle hardness test disc according to claim 1, wherein: the driving motor is fixed on one side of the back of the upper trough frame through the surface of the fixing frame.

4. A particulate hardness test sample disk discharging mechanism according to claim 3, wherein: and more than one detection mark is attached to the lower position of the feeding trough frame, which corresponds to the trough to be detected.

5. The discharge mechanism of a particle hardness test disc according to claim 1, wherein: the diameter of the toothed ring is smaller than that of the switching turntable, and the toothed ring is hidden below the switching turntable.

6. The discharge mechanism of a particle hardness test disc according to claim 5, wherein: the universal ball for reducing friction is arranged at the position below the switching turntable corresponding to the detection position of the particle detection equipment.