CN214826476U - Conveying mesh belt mechanism - Google Patents

Abstract

The utility model relates to a conveying mesh belt mechanism, which comprises a V-shaped chain piece, a chain piece end head part, an end penetrating hole, two chain piece tail feet, two tail foot penetrating holes, a connecting part and a connecting part, wherein a mounting empty part is formed between the two chain piece tail feet; and a spacer connected to the V-shaped chain member. The beneficial effects are that: several materials can be simultaneously transmitted in parallel, so that the material conveying device is more regular; meanwhile, the device can be automatically adjusted, and one or more subareas can be arranged; the disassembly is more convenient, the disassembly of the whole machine is not needed, and the small modules can be independently replaced.

Description

Conveying mesh belt mechanism

Technical Field

The utility model belongs to the technical field of transmission device, especially, relate to conveying mesh belt mechanism.

Background

The instant freezer is a device for quick freezing food in food processing industry, and has wide application in food processing industry, the instant freezer in the prior art mainly comprises an air cooler, a fan and a conveying mechanism in a quick freezing box, frozen products are continuously input and output from the quick freezing box by a conveyor and are rapidly frozen in the conveying process, and the conveying mode of a double-hanging chain and a single-hanging chain dragging and guiding net belt is generally adopted.

The existing conveying belt generally does not have a partition conveying function, one material is conveyed in a single direction, and a plurality of materials cannot be conveyed simultaneously in parallel, so that the conveying belt is inconvenient to adjust.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model adopts the following technical scheme:

a conveying mesh belt mechanism comprises

A V-shaped chain member having

The head part of the chain piece is provided with a head penetrating hole,

the two chain piece tail feet are provided with tail foot through holes and connected to two sides of the tail part of the end part of the chain piece, and a mounting hollow part is formed between the two chain piece tail feet; and

and the spacers are connected and arranged on the V-shaped chain pieces.

In some forms, the spacer is attached to the link end head or the link tail.

In some forms the spacer is attached to the link end head and the spacer is located on an axis of symmetry of the V-link.

In some forms, the chain end head is accessible to the seating void.

In some forms, the link end head portion is shaped to match the seating void.

In some modes, a clamping and embedding opening is formed in one side of the tail pin penetrating hole, and the opening part of the clamping and embedding opening has expanding elasticity. The spacer is detachably connected to the V-shaped chain member.

In some modes, a side branch V-shaped chain piece group is connected to the outer side of the tail foot of any chain piece, and the side branch V-shaped chain piece group consists of a plurality of side branch V-shaped chain pieces.

In some embodiments, the side branch V-shaped chain element has a side branch end through hole and a side branch tail through hole.

In some forms, the side branch V-shaped chain element is also provided with a clamping opening.

In some embodiments, a plurality of said side branch end penetrations are collinear with said end penetration; the lateral branch tail pin penetrating holes and the tail pin penetrating holes are collinear; and a plurality of the clamping and embedding ports are collinear.

The utility model has the advantages that:

several materials can be simultaneously transmitted in parallel, so that the material conveying device is more regular; meanwhile, the device can be automatically adjusted, and one or more subareas can be arranged; the disassembly is more convenient, the disassembly of the whole machine is not needed, and the small modules can be independently replaced.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is another schematic structural diagram of the present invention;

fig. 3 is a schematic view of an expanded structure of the present invention;

fig. 4 is a reference diagram of a usage status of the present invention.

In the figure:

100 spacing parts, 200V-shaped chain parts, 210 chain part end parts, 220 chain part tail pins, 240 arranging empty parts, 250 tail pin through holes, 260 end through holes, 300 clamping and embedding openings, 500 side branch V-shaped chain parts, 510 side branch end through holes and 520 side branch tail pin through holes.

Detailed Description

The following further description of the present invention:

the mesh belt mechanism, as shown in fig. 1, comprises

The V-shaped chain member 200 is not limited to V-shape, and any main body with inconsistent width at both ends should also fall within the scope of the present invention. It is provided with

The chain end head part 210 has an end through hole 260, the rotating shaft rod is inserted into the end through hole 260, so that the chain end head part 210 can rotate on the rotating shaft rod,

two chain piece end legs 220, each of which has an end leg through hole 250, connected to both sides of the tail of the chain piece end head 210, and a mounting hollow 240 is formed between the two chain piece end legs 220; when the conveying mesh belt mechanism is used in a combined mode, the end head portions 210 of the chain elements can be arranged in the placement empty portions 240, and splicing operation is achieved; also comprises

A spacer 100 connected to the V-shaped chain 200; one of the spacers 100 is flat and is vertically disposed on the upper side of the V-shaped chain member 200;

the spacer 100 is attached to either the link end head 210 or the link tail 220.

Spacer 100 is detachably connected to V-shaped link 200; the V-shaped chain member 200 is provided with a strip-shaped slot, and the spacer 100 is inserted into the strip-shaped slot during installation, so that the spacer can be installed. Thereby realize the multipurpose of transmission band mechanism, dismantle the spacer and can transmit bigger material.

The spacer 100 is attached to the chain end head 210 and the spacer 100 is located on the axis of symmetry of the V-chain 200.

The chain end head 210 can enter the seating recess 240.

The chain end head 210 is shaped to match the seating void 240.

When used in tandem as in fig. 4, the plurality of spacers 100 form a strip of isolation belt on the transport track, thereby achieving zoning of the transport belt and forming a plurality of transport zones on the transport belt. A plurality of materials are led to the transmission just can be realized to a transmission band, and the operation is independent mutually.

As shown in fig. 2, a clamping opening 300 is formed at one side of the tail pin through hole 250 and one side of the end head through hole 260, and an opening of the clamping opening 300 has expansion elasticity. The V-shaped chain piece 200 can be installed on the rotating rod through pressing, and meanwhile, the V-shaped chain piece 200 can be detached from the rotating rod through external force.

In an expanded case, as shown in fig. 3, a side branch V-link group is connected to the outside of any one of the link tail legs 220, and the side branch V-link group is composed of a plurality of side branch V-links 500. The wave-like shape is formed, the width of the mechanism is improved, and the installation difficulty is reduced.

Similarly, the bypass V-link 500 has a bypass end through hole 510 and a bypass tail through hole 520 as in the V-link 200 configuration described with reference to fig. 3.

The side branch V-shaped chain member 500 is also provided with a snap-in mouth 300.

A plurality of the side branch end through holes 510 are collinear with the end through hole 260; the side branch tail pin through holes 520 and the tail pin through holes 250 are collinear; a number of the snap-fit ports 300 are collinear. The collinear arrangement of the mechanisms is more convenient for the rotating rod in fig. 3 to penetrate, so that the mechanism in fig. 4 is formed.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. Which all fall within the protection scope of the utility model. The protection scheme of the utility model is based on the appended claims.

Claims (10)

1. The conveying net belt mechanism is characterized by comprising

A V-shaped chain member (200) having

A chain end head part (210) provided with an end head through hole (260),

the two chain piece tail feet (220) are provided with tail foot through holes (250) and connected to two sides of the tail of the chain piece end head part (210), and a mounting hollow part (240) is formed between the two chain piece tail feet (220); and

and a spacer (100) connected to the V-shaped chain (200).

2. The foraminous conveyor belt mechanism of claim 1, wherein the spacers (100) are connected to the chain element end heads (210) or the chain element end feet (220).

3. The belt mechanism according to claim 2, characterized in that the spacers (100) are connected to the chain end heads (210) and the spacers (100) are located on the symmetry axis of the V-shaped chain (200).

4. The foraminous conveyor belt mechanism of claim 1, wherein the chain element end heads (210) are accessible to the mounting pockets (240).

5. The foraminous conveyor belt mechanism of claim 4, wherein the chain element end heads (210) are shaped to match the seating voids (240).

6. The mesh belt conveying mechanism according to claim 1, wherein clamping and embedding openings (300) are formed in one side of the tail leg penetrating hole (250) and one side of the end penetrating hole (260), and the opening parts of the clamping and embedding openings (300) have expanding elasticity; the spacer (100) is detachably connected to the V-shaped link (200).

7. The mesh belt conveyor mechanism according to claim 1, characterized in that a side branch V-shaped chain element group is connected to the outer side of any one chain element tail foot (220), and the side branch V-shaped chain element group is composed of a plurality of side branch V-shaped chain elements (500).

8. The mesh belt conveyor mechanism according to claim 7, characterized in that the side branch V-chain element (500) has a side branch end through hole (510) and a side branch tail through hole (520).

9. The mesh belt conveyor mechanism according to claim 8, characterized in that the side branch V-chain members (500) are also provided with snap-in notches (300).

10. The mesh belt conveyor mechanism according to claim 9, wherein a plurality of said side branch end through holes (510) and said end through holes (260) are collinear; the side branch tail pin penetrating holes (520) and the tail pin penetrating holes (250) are collinear; a plurality of the clamping ports (300) are collinear.

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