CN219315206U - Stacked sedimentation triangle structure - Google Patents

Abstract

The utility model provides a stacked sedimentation triangle structure, wherein a sedimentation triangle component and a driving component of the sedimentation triangle structure are respectively arranged on the front surface and the rear surface of a sedimentation bottom plate, a driving motor drives a sedimentation control plate to move left and right relative to the sedimentation bottom plate, a travel groove is arranged on the sedimentation control plate, the sedimentation triangle is connected with a sedimentation bearing, and the sedimentation bearing is arranged in the travel groove. In the settlement triangular structure, a plurality of groups of settlement triangular plates are arranged on the settlement bottom plate, and the plurality of groups of settlement triangular plates are arranged in a stacked manner within a limited system center distance, so that the effective working surface of a single settlement triangular plate is enlarged.

Description

Stacked sedimentation triangle structure

Technical Field

The utility model relates to the technical field of computerized flat knitting machines, in particular to a stacked sedimentation triangle structure.

Background

The common sedimentation triangle structure adopted by the conventional computerized flat knitting machine has the defect that the effective working surface of the sedimentation triangle is small due to the limitation of the center distance of the system, and the function of the sedimentation triangle is influenced during knitting.

Therefore, there is an urgent need to make the knitting more stable and efficient by forming a sedimentation triangle structure with a plurality of sets of sedimentation triangle components and driving components which are stacked.

Disclosure of Invention

In order to overcome the problems in the prior art, the utility model provides a stacked sedimentation triangle structure.

The utility model provides the following technical scheme:

the utility model provides a pile-up formula sedimentation triangle structure, sedimentation triangle subassembly and the drive assembly of sedimentation triangle structure are arranged in respectively and are subsided the bottom plate front and back two sides, and driving motor drives the sedimentation control board and controls the removal for subsidence bottom plate, is equipped with the travel groove on the sedimentation control board, and sedimentation triangle connects the sedimentation bearing, the sedimentation bearing is arranged in the travel groove.

Further, the left sedimentation triangle and the right sedimentation triangle are respectively positioned at the lower stroke position; the left sedimentation triangle is positioned at an upper stroke position, the right sedimentation triangle is positioned at a lower stroke position, and a left sedimentation triangle transition position is formed at the overlapping position of the left sedimentation triangle and the right sedimentation triangle; the right sedimentation triangle is in an upper stroke position, the left sedimentation triangle is in a lower stroke position, and three movement modes of a right sedimentation triangle transition position are formed at the overlapping position of the right sedimentation triangle and the left sedimentation triangle.

Further, a gear is arranged at the output shaft end of the driving motor, a gear row is arranged on the sedimentation control plate, and the gear is meshed with the gear row.

Further, the sedimentation triangle assembly comprises a left sedimentation triangle, a right sedimentation triangle, an outer return triangle and an inner return triangle, wherein stroke grooves are formed in the left sedimentation triangle and the right sedimentation triangle, the outer return triangle is fixedly arranged on the outer side of the sedimentation triangle assembly, and the inner return triangle is fixedly arranged between two adjacent groups of sedimentation triangle assemblies.

Further, the driving assembly comprises a left sliding block and a right sliding block, a sliding block limiting groove is formed in the sedimentation bottom plate, and the left sliding block and the right sliding block are respectively arranged in the left sliding block limiting groove and the right sliding block limiting groove.

Further, the back surfaces of the left sliding block and the right sliding block are respectively provided with a left sedimentation triangular bearing and a right sedimentation triangular bearing, the left sedimentation triangular bearing and the right sedimentation triangular bearing are arranged in a travel groove of a sedimentation control plate, and the back surface of the sedimentation bottom plate is provided with a control plate limiting groove; the travel groove is an upper travel groove, a transition travel groove and a lower travel groove in sequence.

Furthermore, the driving motor does not work, the sedimentation control plate does not displace, the left sedimentation triangle bearing and the right sedimentation triangle bearing are arranged in a lower stroke groove of the sedimentation control plate, and the left sedimentation triangle and the right sedimentation triangle are both positioned in a lower stroke position; the driving motor drives the gear to rotate, the sedimentation control plate translates rightwards, the left sedimentation triangle bearing passes through the transition travel groove from the lower travel groove to reach the upper travel groove, the left sedimentation triangle is positioned at the upper travel position, the right sedimentation triangle bearing is always positioned at the lower travel groove, the right sedimentation triangle is positioned at the lower travel position, and the overlapping part of the left sedimentation triangle and the right sedimentation triangle forms a left sedimentation triangle transition position; the driving motor drives the gear to rotate, the sedimentation control plate translates leftwards, the right sedimentation triangle bearing reaches the upper stroke groove from the lower stroke groove through the transition stroke groove, the right sedimentation triangle is positioned at the upper stroke position, the left sedimentation triangle bearing is always positioned at the lower stroke groove, the left sedimentation triangle is positioned at the lower stroke position, and the overlapping part of the right sedimentation triangle and the left sedimentation triangle forms the right sedimentation triangle transition position.

By adopting the technical scheme, the utility model has the following beneficial effects:

1. in the settlement triangular structure, a plurality of groups of settlement triangular plates are arranged on the settlement bottom plate, and the plurality of groups of settlement triangular plates are arranged in a stacked manner within a limited system center distance, so that the effective working surface of a single settlement triangular plate is enlarged.

2. The left sedimentation triangle and the right sedimentation triangle are overlapped with each other, so that the length of the travel groove is increased, the left sedimentation triangle and the right sedimentation triangle can realize the up-and-down reciprocating movement, the overlapped parts of the sedimentation triangles are not interfered with each other, and the travel groove of the sedimentation triangle is longer in a limited space.

3. According to the settlement triangle structure, three different settlement actions can be formed according to different upper and lower arrangement positions of the settlement triangle, so that the diversity of knitting functions is greatly increased.

Drawings

FIG. 1 is a schematic view of the construction of the sedimentation triangle assembly of the present utility model.

Fig. 2 is a schematic structural view of the driving assembly of the present utility model.

Fig. 3 is a schematic diagram of the installation of the motor with the sedimentation triangle structure.

Fig. 4 is a schematic installation view of the sedimentation control plate of the sedimentation triangle structure of the present utility model.

FIG. 5 is a schematic diagram of the assembly of the sedimentation triangle structure of the present utility model.

FIG. 6 is a schematic diagram of a sedimentation triangle construction method according to the present utility model.

FIG. 7 is a schematic diagram of a sedimentation triangle method according to the present utility model.

FIG. 8 is a schematic diagram of a sedimentation triangle construction method of the present utility model.

Description of the reference numerals: A. a sedimentation bottom plate; a1, a left sliding block limiting groove; a2, a right sliding block limiting groove; a3, a control board limiting groove; B. a left sedimentation triangle; b1, left sedimentation triangle downstroke position; b2, left sedimentation triangle upper stroke position; b3, a left sedimentation triangle travel groove; BC. A left sedimentation triangle transition position; C. right sedimentation triangle; c1, right sedimentation triangle downstroke position; c2, right sedimentation triangle upper stroke position; c3, a right sedimentation triangle travel groove; CB. Right settling triangle transition position; D. an outer return triangle; E. an inner return triangle; F. a sedimentation control plate; f1, an upper travel groove; f2, a transition travel groove; f3, a lower travel groove; f4, tooth row; G. a fixing seat; H. a cover plate; I. a motor base; J. a motor plate; K. a driving motor; l, gears; m1, a left sliding block; m2, a right sliding block; n1, a left sedimentation triangle bearing; n2, right sedimentation triangle bearing.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the drawings and detailed description are only intended to illustrate the utility model and are not intended to limit the utility model.

Example 1

As shown in figures 1-5, the utility model provides a stacked sedimentation triangle structure, which consists of a plurality of groups of sedimentation triangle components and driving components which are stacked, wherein the sedimentation triangle components are arranged on the front surface of a sedimentation bottom plate A, the driving components are arranged on the back surface of the sedimentation bottom plate A, the sedimentation triangle components comprise a left sedimentation triangle B, a right sedimentation triangle C, an outer return triangle D and an inner return triangle E, a stroke groove B3 is formed on the left sedimentation triangle B and the right sedimentation triangle C, when the left sedimentation triangle and the right sedimentation triangle are at the same level, the stroke grooves are overlapped in the height direction to form a straight groove, and when the left sedimentation triangle and the right sedimentation triangle are not at the same level, the stroke grooves are connected by a transition stroke groove to form an upper and lower stroke groove.

The stroke groove can accommodate the passage of the selector butts, the needle selecting piece is positioned at the initial position when the sedimentation triangle is positioned at the lower stroke position, the needle selecting piece is positioned at the working position when the sedimentation triangle is positioned at the upper stroke position, the outer return triangle D is fixedly arranged on the outer side of the sedimentation triangle component, and the inner return triangle E is fixedly arranged between two adjacent groups of sedimentation triangle components.

The driving assembly comprises a left sliding block M1 and a right sliding block M2, a sliding block limiting groove is formed in a sedimentation bottom plate A, the left sliding block M1 and the right sliding block M2 are respectively arranged in the left sliding block limiting groove A1 and the right sliding block limiting groove A2, the sliding blocks can slide up and down in the sliding block limiting groove, a left sedimentation triangular bearing N1 and a right sedimentation triangular bearing N2 are respectively arranged on the back surfaces of the left sliding block M1 and the right sliding block M2, the left sedimentation triangular bearing N1 and the right sedimentation triangular bearing N2 are arranged in a travel groove of a sedimentation control plate F, a control plate limiting groove A3 is formed in the back surface of the sedimentation bottom plate A, the sedimentation control plate F can move left and right in the limiting groove A3, a fixing seat G, a cover plate H and a motor seat I are arranged on the back surface of the sedimentation bottom plate A, a motor plate J is arranged on the motor seat I, a driving motor K is arranged on the motor plate J, a gear L is arranged at the output shaft end of the driving motor K, and the gear L is meshed with a gear row F4 on the sedimentation control plate F.

The sedimentation control board F is arranged in a control board limiting groove A3 of the sedimentation bottom board A, and can horizontally slide transversely along the control board limiting groove A3, a travel groove is formed in the sedimentation control board A3 and is divided into an upper travel groove F1, a transition travel groove F2 and a lower travel groove F3, a gear row F4 is formed in the other side of the travel groove, a driving motor K drives a gear L to rotate, and the sedimentation control board F is directly driven to slide left and right through meshing transmission.

Example 2

The different vertical arrangement positions of the sedimentation cams can form three different sedimentation actions, as shown in fig. 6, action one: the driving motor K does not work, the sedimentation control plate F does not displace, the left sedimentation triangle bearing N1 and the right sedimentation triangle bearing N2 are arranged in the lower stroke groove F3 of the sedimentation control plate F, the left sedimentation triangle B and the right sedimentation triangle C are positioned at lower stroke positions B1 and C1, the left sedimentation triangle stroke groove B3 and the right sedimentation triangle stroke groove C3 are positioned at the same horizontal height, and at the moment, the sinker is positioned at the initial position.

As shown in fig. 7, the second motion, the driving motor K drives the gear L to rotate, the sedimentation control board F translates rightward, the left sedimentation triangle bearing N1 passes through the transition travel slot F2 from the lower travel slot F3 to reach the upper travel slot F1, the left sedimentation triangle B is at the upper travel position B2, the right sedimentation triangle bearing N2 is always at the lower travel slot F3, the right sedimentation triangle C is at the lower travel position C1, the left sedimentation triangle travel slot B3 is higher than the right sedimentation triangle travel slot C3, the overlapping part of the left sedimentation triangle B and the right sedimentation triangle C forms the left sedimentation triangle transition position BC, at this time, the sinker corresponding to the left sedimentation triangle B is in the working state, and the sinker corresponding to the right sedimentation triangle C is in the initial state.

As shown in fig. 8, the third motion, the driving motor K drives the gear L to rotate, the sedimentation control F plate translates leftwards, the right sedimentation triangle bearing N2 passes through the transition travel groove F2 from the lower travel groove F3 to reach the upper travel groove F1, the right sedimentation triangle C is at the upper travel position C2, the left sedimentation triangle bearing N1 is always at the lower travel groove F3, the left sedimentation triangle B is at the lower travel position B1, the right sedimentation triangle travel groove B3 is higher than the left sedimentation triangle travel groove C3, the overlapping part of the right sedimentation triangle and the left sedimentation triangle forms the right sedimentation triangle transition position CB, at this time, the sinker corresponding to the left sedimentation triangle B is at the initial state, and the sinker corresponding to the right sedimentation triangle C is at the working state.

The foregoing examples merely illustrate embodiments of the utility model and are described in more detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (6)

1. The utility model provides a pile-up formula sedimentation triangle structure, sedimentation triangle subassembly and the drive assembly of sedimentation triangle structure are arranged in respectively in sedimentation bottom plate front and back two sides, its characterized in that, driving motor drive sedimentation control panel is left and right sides for sedimentation bottom plate and is removed, is equipped with the travel groove on the sedimentation control panel, and sedimentation triangle connects the sedimentation bearing, the sedimentation bearing is arranged in the travel groove.

2. The stacked settling triangle structure of claim 1, wherein the left settling triangle and the right settling triangle are in a downstroke position; the left sedimentation triangle is positioned at an upper stroke position, the right sedimentation triangle is positioned at a lower stroke position, and a left sedimentation triangle transition position is formed at the overlapping position of the left sedimentation triangle and the right sedimentation triangle; the right sedimentation triangle is in an upper stroke position, the left sedimentation triangle is in a lower stroke position, and three movement modes of a right sedimentation triangle transition position are formed at the overlapping position of the right sedimentation triangle and the left sedimentation triangle.

3. The stacked sedimentation triangle structure according to claim 1, wherein a gear is arranged at the output shaft end of the driving motor, a tooth row is arranged on the sedimentation control plate, and the gear is meshed with the tooth row.

4. The stacked sedimentation triangle structure of claim 3, wherein the sedimentation triangle assembly comprises a left sedimentation triangle, a right sedimentation triangle, an outer return triangle and an inner return triangle, wherein the left sedimentation triangle and the right sedimentation triangle are provided with travel grooves, the outer return triangle is fixedly arranged on the outer side of the sedimentation triangle assembly, and the inner return triangle is fixedly arranged between two adjacent groups of sedimentation triangle assemblies.

5. The stacked sedimentation triangle structure of claim 4, wherein the driving assembly comprises a left slider and a right slider, the sedimentation bottom plate is provided with a slider limit groove, and the left slider and the right slider are respectively arranged in the left slider limit groove and the right slider limit groove.

6. The stacked sedimentation triangle structure according to claim 5, wherein the back surfaces of the left slider and the right slider are respectively provided with a left sedimentation triangle bearing and a right sedimentation triangle bearing, the left sedimentation triangle bearing and the right sedimentation triangle bearing are arranged in a travel groove of a sedimentation control plate, and the back surface of the sedimentation bottom plate is provided with a control plate limiting groove; the travel groove is an upper travel groove, a transition travel groove and a lower travel groove in sequence.

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