CN214166603U - Glass manages transportation and uses antidetonation device - Google Patents

Abstract

The utility model provides an anti-seismic device for glass tube transportation, which relates to the technical field of glass tube transportation and comprises a base, a first fixed block, a second fixed block, a first roller, a second roller, a first barrel, a second barrel, a first spring, a second spring, a third spring, a fourth spring, a first vertical rod, a second vertical rod, a supporting body, a first sliding block, a second sliding block, a first threaded rod and a second threaded rod; utilize first threaded rod and second threaded rod respectively rotation regulation first slider and the distance between the second slider to make things convenient for placing of glass pipe and realize fixedly, first montant and second montant can utilize third spring and fourth spring to realize vertical buffering in first barrel and the inside realization of second barrel simultaneously, first barrel and second barrel utilize first spring and second spring to realize horizontal buffering on the base, utilize two gyro wheels to realize transporting, the shock resistance of glass pipe transportation in-process has effectively been improved.

Description

Glass manages transportation and uses antidetonation device

Technical Field

The utility model relates to a glass manages transportation technology field, especially relates to a glass manages transportation and uses antidetonation device.

Background

The glass tube is a non-metal tube, and is divided into four types, namely a common glass tube, a chemical glass tube, a neutral glass tube and a high borosilicate glass tube, and the glass tube belongs to a fragile product, so that a special transportation mechanism is needed to protect the safety of the transportation process in the production and transportation processes.

At present, the device adopted in the transferring process of the glass tube only can fix the glass tube per se, but cannot realize good integral anti-seismic effect, and the glass tube is easily damaged in the transferring process, so that the quality of the glass tube is influenced; therefore, the technical problem to be solved by the technical personnel in the field is to provide the anti-seismic device for transferring the glass tube.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a glass manages transportation and uses antidetonation device to solve the problem that is difficult to realize the antidetonation effect in the glass manages transportation.

Based on above-mentioned purpose, the utility model provides a glass manages antidetonation device for transportation, include:

the device comprises a base, a first fixing block and a second fixing block are fixedly arranged on two sides of the upper end face of the base respectively, and a first roller and a second roller are fixedly arranged on two sides of the lower end face of the base respectively;

a first barrel and a second barrel are respectively arranged between the first fixing block and the second fixing block, and the bottom of the first barrel and the bottom of the second barrel are respectively connected with the upper end face of the base in a sliding manner;

a first spring is fixedly arranged between the inner side surface of the first fixed block and the outer side wall of the first barrel, and a second spring is fixedly arranged between the inner side surface of the second fixed block and the outer side wall of the second barrel;

a third spring is arranged in the first cylinder, and the lower end of the third spring is fixedly connected with the first cylinder; a fourth spring is arranged in the second cylinder, and the lower end of the fourth spring is fixedly connected with the second cylinder;

a first vertical rod is arranged above the first barrel, and the lower end of the first vertical rod is positioned inside the first barrel and is fixedly connected with the upper end of the third spring; a second vertical rod is arranged above the second cylinder, and the lower end of the second vertical rod is positioned in the second cylinder and is fixedly connected with the upper end of the fourth spring; the first vertical rod is connected with the inner part of the first cylinder body in a sliding manner, and the second vertical rod is connected with the inner part of the second cylinder body in a sliding manner;

a support body is arranged above the first vertical rod and the second vertical rod, and the lower end surface of the support body is fixedly connected with the first vertical rod and the second vertical rod respectively;

the upper end surface of the supporting body is provided with a groove, and a first sliding block and a second sliding block are respectively arranged in the groove in a sliding manner; a first threaded rod is arranged on one side of the support body in a threaded through mode, the head end of the first threaded rod is located on the outer side of the support body, and the tail end of the first threaded rod is in contact with the first sliding block; and a second threaded rod is arranged on the other side of the support body in a threaded through manner, the head end of the second threaded rod is positioned on the outer side of the support body, and the tail end of the second threaded rod is in contact with the second sliding block.

Preferably, the inner side surface of the first sliding block is fixedly provided with first elastic cotton, and the inner side surface of the second sliding block is fixedly provided with second elastic cotton.

Preferably, the first threaded rod has a transverse length equal to that of the second threaded rod, and the axial length of the first threaded rod is less than 1/2 of the transverse length of the support body.

Preferably, the longitudinal length of the first vertical rod is equal to that of the second vertical rod, and the longitudinal length of the first vertical rod is greater than the longitudinal height of the first cylinder.

Preferably, the transverse width of the first vertical rod is equal to that of the second vertical rod, and the transverse width of the first vertical rod is equal to the inner diameter of the first cylinder.

Preferably, the support body is U-shaped, the lateral thickness of both sides of the support body is equal, and the lateral thickness of one side of the support body is smaller than the lateral length of the corresponding threaded rod.

Preferably, the transverse length of the supporting body is smaller than the transverse distance between the first fixing block and the second fixing block.

From the above, the utility model provides an antidetonation device for glass tube transportation, including base, first fixed block, second fixed block, first gyro wheel, second gyro wheel, first barrel, second barrel, first spring, second spring, third spring, fourth spring, first montant, second montant, supporter, first slider, second slider, first threaded rod and second threaded rod; the first threaded rod and the second threaded rod are utilized to respectively rotate and adjust the distance between the first sliding block and the second sliding block so as to facilitate the placement of the glass tube and realize fixation, meanwhile, the first vertical rod and the second vertical rod can utilize a third spring and a fourth spring to realize longitudinal buffering inside the first barrel and the second barrel, the first barrel and the second barrel utilize the first spring and the second spring to realize transverse buffering on the base, and the two rollers are utilized to realize transportation, so that the shock resistance of the glass tube in the transportation process is effectively improved; the utility model has the advantages that the whole structure is simple, the antidetonation effect in the glass pipe transportation process can be effectively promoted.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a front view of the overall structure of an anti-seismic device for transporting glass tubes according to an embodiment of the present invention;

FIG. 2 is a top view of the overall structure of an anti-seismic device for transporting glass tubes according to an embodiment of the present invention;

in the figure:

1. a base; 2. a first fixed block; 3. a second fixed block; 4. a first roller; 5. a second roller; 6. a first cylinder; 7. a second cylinder; 8. a first spring; 9. a second spring; 10. a third spring; 11. a fourth spring; 12. a first vertical bar; 13. a second vertical bar; 14. a support body; 15. a first slider; 16. a second slider; 17. a first threaded rod; 18. a second threaded rod; 19. and (5) transferring the glass tube.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings.

It should be noted that unless otherwise defined, technical or scientific terms used in the embodiments of the present invention should have the ordinary meaning as understood by those having ordinary skill in the art to which the present disclosure belongs. The use of "first," "second," and similar terms in this disclosure is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

FIG. 1 is a front view of an overall structure of an anti-seismic device for transporting glass tubes according to an embodiment of the present invention; FIG. 2 is a top view of the overall structure of an anti-seismic device for transporting glass tubes according to an embodiment of the present invention; the utility model provides a glass manages transportation and uses antidetonation device, include:

the base 1, the up end both sides of base 1 are fixed respectively and are provided with first fixed block 2 and second fixed block 3, the lower terminal surface both sides of base 1 are fixed respectively and are provided with first gyro wheel 4 and second gyro wheel 5.

A first barrel 6 and a second barrel 7 are respectively arranged between the first fixing block 2 and the second fixing block 3, and the bottom of the first barrel 6 and the bottom of the second barrel 7 are respectively connected with the upper end face of the base 1 in a sliding mode.

A first spring 8 is fixedly arranged between the inner side surface of the first fixing block 2 and the outer side wall of the first barrel 6, and a second spring 9 is fixedly arranged between the inner side surface of the second fixing block 3 and the outer side wall of the second barrel 7.

A third spring 10 is arranged in the first cylinder 6, and the lower end of the third spring 10 is fixedly connected with the first cylinder 6; a fourth spring 11 is arranged inside the second cylinder 7, and the lower end of the fourth spring 11 is fixedly connected with the second cylinder 7.

A first vertical rod 12 is arranged above the first cylinder 6, and the lower end of the first vertical rod 12 is positioned in the first cylinder 6 and is fixedly connected with the upper end of the third spring 10; a second vertical rod 13 is arranged above the second cylinder 7, and the lower end of the second vertical rod 13 is positioned in the second cylinder 7 and is fixedly connected with the upper end of the fourth spring 11; the first vertical rod 12 is connected with the inside of the first cylinder 6 in a sliding manner, and the second vertical rod 13 is connected with the inside of the second cylinder 7 in a sliding manner.

A supporting body 14 is arranged above the first vertical rod 12 and the second vertical rod 13, and the lower end face of the supporting body 14 is fixedly connected with the first vertical rod 12 and the second vertical rod 13 respectively.

A groove is formed in the upper end surface of the support body 14, and a first sliding block 15 and a second sliding block 16 are respectively arranged in the groove in a sliding manner; a first threaded rod 17 is arranged on one side of the support body 14 in a threaded through manner, the head end of the first threaded rod 17 is positioned on the outer side of the support body 14, and the tail end of the first threaded rod 17 is in contact with the first sliding block 15; a second threaded rod 18 is arranged on the other side of the support body 14 in a threaded through manner, the head end of the second threaded rod 18 is positioned on the outer side of the support body 14, and the tail end of the second threaded rod 18 is in contact with the second sliding block 16.

The utility model provides an anti-seismic device for transferring glass tubes, which comprises a base 1, a first fixed block 2, a second fixed block 3, a first roller 4, a second roller 5, a first barrel 6, a second barrel 7, a first spring 8, a second spring 9, a third spring 10, a fourth spring 11, a first vertical rod 12, a second vertical rod 13, a support body 14, a first slider 15, a second slider 16, a first threaded rod 17 and a second threaded rod 18; the distance between the first sliding block 15 and the second sliding block 16 is respectively adjusted in a rotating mode through the first threaded rod 17 and the second threaded rod 18, so that glass tubes can be conveniently placed and fixed, meanwhile, the first vertical rod 12 and the second vertical rod 13 can achieve longitudinal buffering inside the first barrel 6 and the second barrel 7 through the third spring 10 and the fourth spring 11, the first barrel 6 and the second barrel 7 achieve transverse buffering on the base 1 through the first spring 8 and the second spring 9, transfer is achieved through the two rollers, and shock resistance of the glass tubes in the transfer process is effectively improved; the utility model has the advantages that the whole structure is simple, the antidetonation effect in the glass pipe transportation process can be effectively promoted.

The utility model also provides a glass manages transportation and uses antidetonation device, include:

the base 1, the up end both sides of base 1 are fixed respectively and are provided with first fixed block 2 and second fixed block 3, the lower terminal surface both sides of base 1 are fixed respectively and are provided with first gyro wheel 4 and second gyro wheel 5.

A first barrel 6 and a second barrel 7 are respectively arranged between the first fixing block 2 and the second fixing block 3, and the bottom of the first barrel 6 and the bottom of the second barrel 7 are respectively connected with the upper end face of the base 1 in a sliding mode.

A first spring 8 is fixedly arranged between the inner side surface of the first fixing block 2 and the outer side wall of the first barrel 6, and a second spring 9 is fixedly arranged between the inner side surface of the second fixing block 3 and the outer side wall of the second barrel 7.

A third spring 10 is arranged in the first cylinder 6, and the lower end of the third spring 10 is fixedly connected with the first cylinder 6; a fourth spring 11 is arranged inside the second cylinder 7, and the lower end of the fourth spring 11 is fixedly connected with the second cylinder 7.

A first vertical rod 12 is arranged above the first cylinder 6, and the lower end of the first vertical rod 12 is positioned in the first cylinder 6 and is fixedly connected with the upper end of the third spring 10; a second vertical rod 13 is arranged above the second cylinder 7, and the lower end of the second vertical rod 13 is positioned in the second cylinder 7 and is fixedly connected with the upper end of the fourth spring 11; the first vertical rod 12 is connected with the inside of the first cylinder 6 in a sliding manner, and the second vertical rod 13 is connected with the inside of the second cylinder 7 in a sliding manner.

A supporting body 14 is arranged above the first vertical rod 12 and the second vertical rod 13, and the lower end face of the supporting body 14 is fixedly connected with the first vertical rod 12 and the second vertical rod 13 respectively.

A groove is formed in the upper end surface of the support body 14, and a first sliding block 15 and a second sliding block 16 are respectively arranged in the groove in a sliding manner; a first threaded rod 17 is arranged on one side of the support body 14 in a threaded through manner, the head end of the first threaded rod 17 is positioned on the outer side of the support body 14, and the tail end of the first threaded rod 17 is in contact with the first sliding block 15; a second threaded rod 18 is arranged on the other side of the support body 14 in a threaded through manner, the head end of the second threaded rod 18 is positioned on the outer side of the support body 14, and the tail end of the second threaded rod 18 is in contact with the second sliding block 16.

The inner side surface of the first sliding block 15 is fixedly provided with first elastic cotton, and the inner side surface of the second sliding block 16 is fixedly provided with second elastic cotton.

Wherein the transverse length of the first threaded rod 17 is equal to the transverse length of the second threaded rod 18, and the axial length of the first threaded rod 17 is less than 1/2 of the transverse length of the support body 14.

The longitudinal length of the first vertical rod 12 is equal to the longitudinal length of the second vertical rod 13, and the longitudinal length of the first vertical rod 12 is greater than the longitudinal height of the first barrel 6.

The transverse width of the first vertical rod 12 is equal to that of the second vertical rod 13, and the transverse width of the first vertical rod 12 is equal to the inner diameter of the first cylinder 6.

The supporting body 14 is U-shaped, the lateral thicknesses of the two sides of the supporting body 14 are equal, and the lateral thickness of one side of the supporting body 14 is smaller than the lateral length of the corresponding threaded rod.

Wherein, the transverse length of the supporting body 14 is smaller than the transverse distance between the first fixing block 2 and the second fixing block 3.

The utility model provides an anti-seismic device for transferring glass tubes, which comprises a base 1, a first fixed block 2, a second fixed block 3, a first roller 4, a second roller 5, a first barrel 6, a second barrel 7, a first spring 8, a second spring 9, a third spring 10, a fourth spring 11, a first vertical rod 12, a second vertical rod 13, a support body 14, a first slider 15, a second slider 16, a first threaded rod 17 and a second threaded rod 18; the distance between the first sliding block 15 and the second sliding block 16 is respectively adjusted in a rotating mode through the first threaded rod 17 and the second threaded rod 18, so that glass tubes can be conveniently placed and fixed, meanwhile, the first vertical rod 12 and the second vertical rod 13 can achieve longitudinal buffering inside the first barrel 6 and the second barrel 7 through the third spring 10 and the fourth spring 11, the first barrel 6 and the second barrel 7 achieve transverse buffering on the base 1 through the first spring 8 and the second spring 9, transfer is achieved through the two rollers, and shock resistance of the glass tubes in the transfer process is effectively improved; the utility model has the advantages that the whole structure is simple, the antidetonation effect in the glass pipe transportation process can be effectively promoted.

When the anti-seismic device for transferring the glass tubes provided by the utility model is used, the length of the general glass tubes is longer, so that two or more than two devices provided by the utility model can be used together, and the two devices provided by the utility model can be mutually fixedly connected and can also be used independently when in use; when the glass tube clamping device is used, firstly, the first threaded rod 17 and the second threaded rod 18 are manually adjusted respectively to adjust the width between the first sliding block 15 and the second sliding block 16, one end of a glass tube 19 to be transported is placed in a groove on the upper end face of the supporting body 14, the two threaded rods are adjusted to enable the two ends of the first sliding block 15 and the second sliding block 16 to clamp the glass tube, elastic cotton is arranged on the inner side faces of the first sliding block 15 and the second sliding block 16 respectively, and damage to the glass tube in the clamping process is prevented; in the transportation, remove through the gyro wheel of bottom the utility model discloses device, when receiving vertical vibrations in the transportation, first montant 12 and second montant 13 can drive the spring motion that corresponds in the barrel that corresponds respectively, and the upper and lower vibrations that receive when transporting by the elasticity of third spring 10 and fourth spring 11 are cushioned, when receiving horizontal vibrations in the transportation, first barrel 6 and second barrel 7 can utilize first spring 8 and second spring 9 to realize horizontal buffering on base 1 respectively, the utility model has the advantages of simple overall structure, can effectively promote the antidetonation effect in the glass pipe transportation.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to these examples; within the idea of the invention, also technical features in the above embodiments or in different embodiments can be combined, steps can be implemented in any order, and there are many other variations of the different aspects of the invention as described above, which are not provided in detail for the sake of brevity.

The present embodiments are intended to embrace all such alternatives, modifications and variances which fall within the broad scope of the appended claims. Therefore, any omission, modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (7)

1. The utility model provides a glass pipe is transported and is used antidetonation device which characterized in that includes:

the device comprises a base, a first fixing block and a second fixing block are fixedly arranged on two sides of the upper end face of the base respectively, and a first roller and a second roller are fixedly arranged on two sides of the lower end face of the base respectively;

a first barrel and a second barrel are respectively arranged between the first fixing block and the second fixing block, and the bottom of the first barrel and the bottom of the second barrel are respectively connected with the upper end face of the base in a sliding manner;

a first spring is fixedly arranged between the inner side surface of the first fixed block and the outer side wall of the first barrel, and a second spring is fixedly arranged between the inner side surface of the second fixed block and the outer side wall of the second barrel;

a third spring is arranged in the first cylinder, and the lower end of the third spring is fixedly connected with the first cylinder;

a fourth spring is arranged in the second cylinder, and the lower end of the fourth spring is fixedly connected with the second cylinder;

a first vertical rod is arranged above the first barrel, and the lower end of the first vertical rod is positioned inside the first barrel and is fixedly connected with the upper end of the third spring; a second vertical rod is arranged above the second cylinder, and the lower end of the second vertical rod is positioned in the second cylinder and is fixedly connected with the upper end of the fourth spring; the first vertical rod is connected with the inner part of the first cylinder body in a sliding manner, and the second vertical rod is connected with the inner part of the second cylinder body in a sliding manner;

a support body is arranged above the first vertical rod and the second vertical rod, and the lower end surface of the support body is fixedly connected with the first vertical rod and the second vertical rod respectively;

the upper end surface of the supporting body is provided with a groove, and a first sliding block and a second sliding block are respectively arranged in the groove in a sliding manner; a first threaded rod is arranged on one side of the support body in a threaded through mode, the head end of the first threaded rod is located on the outer side of the support body, and the tail end of the first threaded rod is in contact with the first sliding block; and a second threaded rod is arranged on the other side of the support body in a threaded through manner, the head end of the second threaded rod is positioned on the outer side of the support body, and the tail end of the second threaded rod is in contact with the second sliding block.

2. The anti-seismic device for glass tube transfer according to claim 1, wherein a first elastic cotton is fixedly arranged on the inner side surface of the first sliding block, and a second elastic cotton is fixedly arranged on the inner side surface of the second sliding block.

3. An anti-seismic device for glass tube transfer as defined in claim 2, wherein the first threaded rod has a transverse length equal to that of the second threaded rod, and the first threaded rod has an axial length less than 1/2 of the transverse length of the support body.

4. An anti-seismic device for glass tube transportation according to claim 3, wherein the longitudinal length of the first vertical rod is equal to the longitudinal length of the second vertical rod, and the longitudinal length of the first vertical rod is greater than the longitudinal height of the first cylinder.

5. An anti-seismic device for glass tube transportation according to claim 4, wherein the lateral width of the first vertical rod is equal to the lateral width of the second vertical rod, and the lateral width of the first vertical rod is equal to the inner diameter of the first cylinder.

6. An anti-seismic device for glass tube transfer according to claim 5, wherein the support body is U-shaped, the lateral thickness of both sides of the support body is equal, and the lateral thickness of one side of the support body is smaller than the lateral length of the corresponding threaded rod.

7. An anti-seismic device for glass tube transfer according to claim 6, wherein the support has a transverse length smaller than a transverse distance between the first fixed block and the second fixed block.

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