CN214110951U - Wire mesh center distance adjusting mechanism for slicing machine - Google Patents
Wire mesh center distance adjusting mechanism for slicing machine Download PDFInfo
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- CN214110951U CN214110951U CN202022840531.5U CN202022840531U CN214110951U CN 214110951 U CN214110951 U CN 214110951U CN 202022840531 U CN202022840531 U CN 202022840531U CN 214110951 U CN214110951 U CN 214110951U
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- eccentric
- bearing box
- inner hole
- wire mesh
- center distance
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Abstract
The utility model discloses a wire mesh center distance adjusting mechanism for a slicer, which has the technical scheme that the wire mesh center distance adjusting mechanism comprises a frame, wherein a first front inner hole and a second front inner hole are arranged on the front side of the frame, and a first rear inner hole and a second rear inner hole are arranged on the rear side of the frame; an eccentric supporting roller is arranged between the first front inner hole and the first rear inner hole, and a concentric supporting roller is arranged between the second front inner hole and the second rear inner hole; the utility model discloses an eccentric backing roll for the centre of rotation distance between two backing rolls is adjustable in the certain limit, makes single equipment can carry out the cutting of the hard brittle material of unidimensional not, and very big degree has improved the cutting ability of slicer.
Description
Technical Field
The utility model relates to a slicer technical field, more specifically the theory that says so, it relates to a gauze centre-to-centre spacing guiding mechanism for slicer.
Background
In the actual production process, the actual cutting capacity of the slicer is mainly related to the width of the wire mesh in the cutting area. The smaller the width of the wire mesh is, the smaller the size of the material which can be cut into hard and brittle materials is; the larger the wire mesh width, the larger the size of the material that can be cut to be hard and brittle. However, when the size of the brittle material is small, the smaller the width of the wire mesh under the condition of satisfying the cutting, the better the cutting yield, and the yield is reduced correspondingly as the width of the wire mesh is increased. Therefore, the hard and brittle materials with different sizes need to be cut with corresponding width of wire mesh to achieve the best yield. In actual production, the rotating center distance between the supporting rollers cannot be adjusted, so that the cutting capability of the slicing machine is limited, and the cutting yield is influenced.
SUMMERY OF THE UTILITY MODEL
Not enough to prior art exists, the utility model aims to provide a gauze centre-to-centre spacing guiding mechanism for slicer is through setting up eccentric backing roll for the centre-of-rotation distance between two backing rolls is adjustable.
In order to achieve the above purpose, the utility model provides a following technical scheme: a wire mesh center distance adjusting mechanism for a slicer comprises a frame, wherein a first front inner hole and a second front inner hole are formed in the front side of the frame, and a first rear inner hole and a second rear inner hole are formed in the rear side of the frame; and an eccentric supporting roller is arranged between the first front inner hole and the first rear inner hole, and a concentric supporting roller is arranged between the second front inner hole and the second rear inner hole.
The utility model discloses further set up to: the eccentric support roller consists of an eccentric sleeve assembly, a first bearing box assembly and a first main roller.
The utility model discloses further set up to: the eccentric cover assembly comprises a front eccentric cover and a rear eccentric cover, the front eccentric cover is fixed in the first front inner hole, and the rear eccentric cover is fixed in the first rear inner hole.
The utility model discloses further set up to: the first bearing box assembly comprises a first front bearing box and a first rear bearing box, the first front bearing box is fixed in an inner circular hole of the front eccentric sleeve, the first rear bearing box is fixed in an inner circular hole of the rear eccentric sleeve, and the first main roller is arranged between the first front bearing box and the first rear bearing box.
The utility model discloses further set up to: the eccentric supporting roller is composed of an eccentric bearing box assembly and a first main roller.
The utility model discloses further set up to: the eccentric bearing box assembly comprises a front eccentric bearing box and a rear eccentric bearing box, the front eccentric bearing box is fixed in the first front inner hole, and the rear eccentric bearing box is fixed in the first rear inner hole; the first main roller is arranged between the front eccentric bearing box and the rear eccentric bearing box.
The utility model discloses further set up to: the front eccentric bearing box and the rear eccentric bearing box are both eccentric bearing boxes;
the eccentric bearing box comprises an eccentric bearing sleeve which is arranged in the first inner hole or the second inner hole, and an inner side through hole of the eccentric bearing sleeve is eccentrically arranged with the first front inner hole and the second rear inner hole;
and a bearing disposed in the inner through hole of the eccentric bearing housing.
The utility model discloses further set up to: the bearing is provided with a plurality of, and a plurality of bearings are arranged along the axis direction of the inboard through-hole of eccentric bearing cover.
The utility model discloses further set up to: the concentric support roller is composed of a second bearing box assembly and a second main roller.
The utility model discloses further set up to: the second bearing box assembly comprises a second front bearing box and a second rear bearing box, the second front bearing box is fixed in the second front inner hole, and the second rear bearing box is fixed in the second rear inner hole; the second main roller is arranged between the second front bearing box and the second rear bearing box.
To sum up, the utility model discloses compare and have following beneficial effect in prior art: the utility model discloses a set up eccentric backing roll for the centre of rotation distance between two backing rolls is adjustable.
Drawings
FIG. 1 is a schematic view of the overall structure of the first embodiment;
FIG. 2 is a schematic diagram of an embodiment of a current net center distance;
FIG. 3 is a schematic view showing the overall structure of the second embodiment;
FIG. 4 is a schematic view of an eccentric bearing housing according to the second embodiment;
FIG. 5 is a sectional view of an eccentric bearing housing of the second embodiment;
FIG. 6 is a schematic diagram of the center distance of the present invention.
In the figure: 1. a frame; 11. a first main shaft; 12. a second main shaft; 2. a front eccentric sleeve; 3. a rear eccentric sleeve; 4. a first front bearing housing; 5. a first rear bearing housing; 6. a second front bearing housing; 7. a second rear bearing housing; 8. a front eccentric bearing housing; 9. a rear eccentric bearing housing; 91. an eccentric bearing housing; 92. an inner through hole; 93. a bearing; 94. and (4) end covers.
Detailed Description
In order to make those skilled in the art better understand the technical solution of the present invention, the following description, together with the drawings of the present invention, clearly and completely describes the technical solution of the present invention, and based on the embodiments in the present application, other similar embodiments obtained by those skilled in the art without creative efforts shall all belong to the protection scope of the present application. In addition, directional terms such as "upper", "lower", "left", "right", etc. in the following embodiments are directions with reference to the drawings only, and thus, the directional terms are used for illustrating the present invention and not for limiting the present invention.
The present invention will be further described with reference to the accompanying drawings and preferred embodiments.
The first embodiment is as follows: a wire mesh center distance adjusting mechanism for a slicing machine is disclosed, referring to attached figures 1 and 2, the mechanism is arranged at a cutting area of the slicing machine and comprises a frame 1, a first front inner hole and a second front inner hole are formed in the front side of the frame 1, and a first rear inner hole and a second rear inner hole are formed in the rear side of the frame 1; preferably, the centers of the first front inner hole and the first rear inner hole are on the same axis; the centers of the second front inner hole and the second rear inner hole are on the same axis.
An eccentric supporting roller is arranged between the first front inner hole and the first rear inner hole, and a concentric supporting roller is arranged between the second front inner hole and the second rear inner hole. The eccentric supporting roller consists of an eccentric sleeve assembly, a first bearing box assembly and a first main roller; the concentric support roller is composed of a second bearing box assembly and a second main roller. The first main roller is supported by a first main shaft 11 penetrating through the first main roller, and the first main shaft 11 is coaxial with the first main roller; the second main roll is supported by a second spindle 12 passing through the second main roll, the second spindle 12 being coaxial with the second main roll.
The eccentric sleeve assembly comprises a front eccentric sleeve 2 and a rear eccentric sleeve 3, the front eccentric sleeve 2 is fixed in the first front inner hole, the rear eccentric sleeve 3 is fixed in the first rear inner hole, and specifically, the front eccentric sleeve 2 and the rear eccentric sleeve 3 are detachably connected with the frame 1; specifically, the front eccentric sleeve 2 and the rear eccentric sleeve 3 are connected with the frame 1 through bolts; the first bearing box assembly comprises a first front bearing box 4 and a first rear bearing box 5, the first front bearing box 4 is fixed in an inner circular hole of the front eccentric sleeve 2, the first rear bearing box 5 is fixed in an inner circular hole of the rear eccentric sleeve 3, a first main roller is arranged between the first front bearing box 4 and the first rear bearing box 5, and two ends of a first main shaft 11 are respectively supported in the first front bearing box 4 and the first rear bearing box 5. The second bearing box assembly comprises a second front bearing box 6 and a second rear bearing box 7, the second front bearing box 6 is fixed in the second front inner hole, and the second rear bearing box 7 is fixed in the second rear inner hole; a second main roller is arranged between the second front bearing housing 6 and the second rear bearing housing 7, and a second main shaft 12 is supported in the second front bearing housing 6 and the second rear bearing housing 7, respectively. Dense diamond wires distributed between the first main roller and the second main roller form a wire net to cut the hard and brittle materials.
In this embodiment, the center distance of rotation between the front eccentric sleeve 2 and the second front bearing housing 6 is not less than 150mm and not more than 750 mm. Meanwhile, the inner circular hole of the front eccentric sleeve 2 is coaxial with the inner circular hole of the rear eccentric sleeve 3, and the rotation central axes of the second front bearing box 6 and the second rear bearing box 7 are coaxial, so that the rotation central distance between the front eccentric sleeve 2 and the second front bearing box 6 is consistent with the rotation central distance between the rear eccentric sleeve 3 and the second rear bearing box 7.
In this embodiment, the method for adjusting the center distance is that, first, the eccentric support roller and the concentric support roller are fixed on the frame 1; the distance between the rotation centers of the front eccentric sleeve 2 and the second front bearing box 6 and the distance between the rotation centers of the rear eccentric sleeve 3 and the second rear bearing box 7 are L as short as possible and L + Deltar as long as possible, so that the distance between the centers of the rotation shafts of the front eccentric sleeve 2 and the second front bearing box 6 and the distance between the centers of the rotation shafts of the rear eccentric sleeve 3 and the second rear bearing box 7 are changed from L to L + Deltar by rotating the angles of the front eccentric sleeve 2 and the rear eccentric sleeve, and the distance between the centers of the wire mesh in the cutting area is changed from L to L + Deltar. Since the center distance of rotation between the front eccentric sleeve 2 and the second front bearing housing 6 is not less than 150mm and not more than 750mm in the present embodiment, the center distance of the wire mesh in the cutting area can be varied from 150mm to 750mm to accommodate different sizes of hard and brittle materials.
Example two: the present embodiment is another embodiment of a wire mesh center distance adjusting mechanism for a slicer, and referring to fig. 3 and 4, the present embodiment is different from the first embodiment in that an eccentric supporting roller is composed of an eccentric bearing box assembly and a first main roller, the first main roller is supported by a first main shaft 11 passing through the first main roller, and the first main shaft 11 is coaxial with the first main roller.
With reference to fig. 5, the eccentric bearing housing assembly comprises a front eccentric bearing housing 8 and a rear eccentric bearing housing 9; specifically, the front eccentric bearing box 8 and the rear eccentric bearing box 9 are both eccentric bearing boxes, each eccentric bearing box comprises an eccentric bearing sleeve 91 and a bearing 93 arranged in a through hole 92 in the inner side of the eccentric bearing sleeve 91, and the through hole 92 in the inner side of the eccentric bearing sleeve 91 is eccentrically arranged with a first front inner hole and a first rear inner hole; at least one bearing 93 is arranged in each eccentric bearing sleeve 91; two ends of a first main shaft 11 are respectively inserted into bearings of the front eccentric bearing box 8 and the rear eccentric bearing box 9, and the first main shaft 11 is supported through the eccentric bearing box 8 and the rear eccentric bearing box 9; preferably, at least four bearings 93 are arranged in each eccentric bearing sleeve 91 to improve the stability of the bearings 93 for supporting the first main shaft 11; specifically, in the present embodiment, six bearings 93 are disposed in each eccentric bearing sleeve 91, and the six bearings 93 are arranged in the eccentric bearing sleeve 91 along the axial direction of the through hole 92 in the eccentric bearing sleeve 91; the end of the first main shaft 11 is supported by four bearings 93; the eccentric bearing sleeve of the front eccentric bearing box 8 is fixed in the first front inner hole, and the eccentric bearing sleeve of the rear eccentric bearing box 9 is fixed in the first rear inner hole; the first main roller is arranged between the front eccentric bearing box 8 and the rear eccentric bearing box 9; specifically, the eccentric bearing sleeve 91 is detachably connected to the frame 1, and specifically, the eccentric bearing sleeve 91 is connected to the frame 1 by bolts.
Specifically, a plurality of spacer sleeves are further fixed in the eccentric bearing sleeve 91, the number and the arrangement positions of the spacer sleeves are adjusted according to actual conditions, and in the embodiment, three spacer sleeves are arranged; specifically, in this embodiment, end caps 94 are fixed to both ends of the eccentric bearing housing.
The wheelbase of the rotating central shafts of the front eccentric bearing box 8 and the second front bearing box 6 is not less than 150mm and not more than 750 mm; meanwhile, the rotation central axes of the front eccentric bearing box 8 and the rear eccentric bearing box 9 are coaxial, so that the rotation central distance between the front eccentric bearing box 8 and the second front bearing box 6 is consistent with the rotation central distance between the rear eccentric bearing box 9 and the second rear bearing box 7.
In this embodiment, the method for adjusting the center distance is to fix the eccentric support roller and the concentric support roller on the frame 1 first, with reference to fig. 6; the distances between the center axes of rotation of the front and second front bearing housings 8 and 6 and the rear and second rear bearing housings 9 and 7 are at the shortest distance L 'and at the greatest distance L' + Δ r ', and therefore the distances between the center axes of rotation of the front and second front bearing housings 8 and 6 and the rear and second rear bearing housings 9 and 7 can be adjusted to vary between L' and L '+ Δ r' by adjusting the installation angles of the two eccentric bearing housings. And the center distance of the wire mesh in the cutting wire area is changed between L ' and L ' + delta r '. Since the distance between the axes of the front eccentric bearing box 8 and the second front bearing box 6 is not less than 150mm to 750mm in the present embodiment, the distance between the centers of the wire mesh in the cutting area can be varied from 150mm to 750mm to adapt to hard magnetic materials with different sizes.
It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.
Claims (10)
1. The utility model provides a gauze centre-to-centre spacing guiding mechanism for slicer, includes frame (1), its characterized in that: a first front inner hole and a second front inner hole are formed in the front side of the frame (1), and a first rear inner hole and a second rear inner hole are formed in the rear side of the frame (1); and an eccentric supporting roller is arranged between the first front inner hole and the first rear inner hole, and a concentric supporting roller is arranged between the second front inner hole and the second rear inner hole.
2. The wire mesh center distance adjusting mechanism for a slicer according to claim 1, wherein: the eccentric support roller consists of an eccentric sleeve assembly, a first bearing box assembly and a first main roller.
3. The wire mesh center distance adjusting mechanism for a slicer according to claim 2, wherein: the eccentric cover assembly comprises a front eccentric cover (2) and a rear eccentric cover (3), the front eccentric cover (2) is fixed in the first front inner hole, and the rear eccentric cover (3) is fixed in the first rear inner hole.
4. The wire mesh center distance adjusting mechanism for a slicer according to claim 3, wherein: the first bearing box assembly comprises a first front bearing box (4) and a first rear bearing box (5), the first front bearing box (4) is fixed in an inner circular hole of the front eccentric sleeve (2), the first rear bearing box (5) is fixed in an inner circular hole of the rear eccentric sleeve (3), and the first main roller is arranged between the first front bearing box (4) and the first rear bearing box (5).
5. The wire mesh center distance adjusting mechanism for a slicer according to claim 1, wherein: the eccentric supporting roller is composed of an eccentric bearing box assembly and a first main roller.
6. The wire mesh center distance adjusting mechanism for a slicer of claim 5, wherein: the eccentric bearing box assembly comprises a front eccentric bearing box (8) and a rear eccentric bearing box (9), the front eccentric bearing box (8) is fixed in the first front inner hole, and the rear eccentric bearing box (9) is fixed in the first rear inner hole; the first main roller is arranged between the front eccentric bearing box (8) and the rear eccentric bearing box (9).
7. The wire mesh center distance adjusting mechanism for a slicer of claim 6, wherein: the front eccentric bearing box (8) and the rear eccentric bearing box (9) are both eccentric bearing boxes;
the eccentric bearing box comprises an eccentric bearing sleeve (91) which is arranged in the first inner hole or the second inner hole, and an inner side through hole (92) of the eccentric bearing sleeve is eccentrically arranged with the first front inner hole and the second rear inner hole;
and a bearing (93) provided in the inner through hole (92) of the eccentric bearing sleeve (91).
8. The wire mesh center distance adjusting mechanism for a slicer of claim 7, wherein: the bearing (93) is provided with a plurality of bearings (93), and the plurality of bearings (93) are arranged along the axial direction of the through hole (92) on the inner side of the eccentric bearing sleeve (91).
9. The wire mesh center distance adjusting mechanism for a slicer according to claim 1, wherein: the concentric support roller is composed of a second bearing box assembly and a second main roller.
10. The wire mesh center distance adjusting mechanism for a slicer of claim 9, wherein: the second bearing box assembly comprises a second front bearing box (6) and a second rear bearing box (7), the second front bearing box (6) is fixed in the second front inner hole, and the second rear bearing box (7) is fixed in the second rear inner hole; the second main roller is arranged between the second front bearing box (6) and the second rear bearing box (7).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202022840531.5U CN214110951U (en) | 2020-11-30 | 2020-11-30 | Wire mesh center distance adjusting mechanism for slicing machine |
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CN202022840531.5U CN214110951U (en) | 2020-11-30 | 2020-11-30 | Wire mesh center distance adjusting mechanism for slicing machine |
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CN214110951U true CN214110951U (en) | 2021-09-03 |
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CN202022840531.5U Active CN214110951U (en) | 2020-11-30 | 2020-11-30 | Wire mesh center distance adjusting mechanism for slicing machine |
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- 2020-11-30 CN CN202022840531.5U patent/CN214110951U/en active Active
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