CN220465559U - Crystal bar transport vehicle - Google Patents

Abstract

The application relates to a crystal bar transport vehicle, which comprises a carrying device and an auxiliary device, wherein the carrying device is provided with a carrying area for carrying crystal bars; the auxiliary device comprises a connecting part and a cooling part, wherein the connecting part is connected to the carrying device, the connecting part is provided with a first connecting part higher than the carrying area, the cooling part is connected with the first connecting part, and the cooling part is used for cooling the crystal bar in the carrying area. This crystal bar transport vechicle can utilize the cooling part to cool down to carrying the crystal bar in the thing region when transporting the crystal bar for the cooling rate of crystal bar has improved cooling efficiency, and then has improved the design speed of crystal bar, has promoted the circulation efficiency of crystal bar.

Description

Crystal bar transport vehicle

Technical Field

The application relates to the technical field of crystal bar transportation, in particular to a crystal bar transportation vehicle.

Background

The crystal bar is a raw material for manufacturing a crystal silicon battery in a photovoltaic module. In the crystal pulling process, polysilicon is placed into a crucible, and the silicon feedstock is melted in a single crystal furnace and then subsequently manufactured to produce high Wen Jingbang. In the prior art, the produced high Wen Jingbang is placed on an open-type transport vehicle for transportation, a natural cooling mode is adopted for cooling, the cooling efficiency is low, and meanwhile, the circulation efficiency of the crystal bar in the subsequent process is also affected.

Disclosure of Invention

The application provides a crystal bar transport vechicle can improve the cooling efficiency of the crystal bar of its transportation, and then promotes the circulation efficiency of crystal bar.

The application provides a crystal bar transport vehicle, which comprises a carrying device and an auxiliary device, wherein the carrying device is provided with a carrying area for carrying crystal bars; the auxiliary device comprises a connecting part and a cooling part, wherein the connecting part is connected to the carrying device, the connecting part is provided with a first connecting part higher than the carrying area, the cooling part is connected with the first connecting part, and the cooling part is used for cooling the crystal bar in the carrying area.

Optionally, the cooling component has an air outlet, and all or part of the air outlet faces the carrying area.

Optionally, the cooling component is a fan.

Optionally, the fan is provided with rechargeable battery, and first connecting portion is provided with charging portion, charging portion and rechargeable battery electric connection, charging portion can with external power source electric connection to charge rechargeable battery.

Optionally, the first connection portion encloses the carrying area.

Optionally, along the length direction of the carrying area, the projection of the first connecting portion is arc-shaped.

Optionally, a flexible buffer layer is disposed on a side of the first connection portion facing the carrying area.

Optionally, the carrying device includes mounting portions located at two sides of the carrying area in a width direction, the connecting component further includes a second connecting portion, and two ends of the first connecting portion along a circumferential direction of the first connecting portion are connected with the mounting portions through the second connecting portion respectively.

Optionally, the connecting component further includes a second connecting portion, and the first connecting portion is detachably connected with the carrying device through the second connecting portion.

Optionally, a plurality of auxiliary devices are provided, and the plurality of auxiliary devices are arranged along the length direction of the carrying area.

The beneficial effects of this application lie in:

the utility model provides a crystal bar transport vechicle, when transporting the crystal bar, specifically is put the crystal bar in the year thing region of carrying the thing device, owing to be connected with the cooling part on the connecting piece who is connected with carrying the thing device, so can utilize the cooling part to carry the crystal bar cooling in the thing region for the cooling rate of crystal bar has improved cooling efficiency, and then has improved the design speed of crystal bar, has promoted the circulation efficiency of crystal bar.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

FIG. 1 is a schematic diagram of a transporting truck for crystal bars according to an embodiment of the present disclosure during transporting the crystal bars;

FIG. 2 is a schematic diagram of the auxiliary device in FIG. 1;

FIG. 3 is a schematic view of the ingot transport vehicle of FIG. 1;

fig. 4 is a schematic structural diagram of a crystal bar transporting vehicle according to another embodiment of the present disclosure during transporting a crystal bar.

Reference numerals:

10-a crystal bar transport vehicle; 20-crystal bar;

1-a carrying device;

11-cargo area;

2-auxiliary devices;

21-a connecting part;

211-a first connection;

212-a second connection;

213-a charging section;

22-cooling components;

3-a support;

4-roller.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

Detailed Description

For a better understanding of the technical solutions of the present application, embodiments of the present application are described in detail below with reference to the accompanying drawings.

It should be understood that the described embodiments are merely some, but not all, of the embodiments of the present application. All other embodiments, based on the embodiments herein, which would be apparent to one of ordinary skill in the art without making any inventive effort, are intended to be within the scope of the present application.

The terminology used in the embodiments of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this application and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be understood that the term "and/or" as used herein is merely one relationship describing the association of the associated objects, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. In addition, the character "/" herein generally indicates that the front and rear associated objects are an "or" relationship.

It should be noted that, the terms "upper", "lower", "left", "right", and the like in the embodiments of the present application are described in terms of the angles shown in the drawings, and should not be construed as limiting the embodiments of the present application. In the context of this document, it will also be understood that when an element is referred to as being "on" or "under" another element, it can be directly on the other element or be indirectly on the other element through intervening elements.

The crystal bar is manufactured through a crystal pulling process, and particularly can be manufactured by a single crystal furnace, wherein the manufacturing process comprises the steps of charging, melting, seeding, shouldering, shoulder rotating, constant diameter, ending, furnace stopping and bar taking, and after the crystal bar is manufactured, the crystal bar needs to be transported to a designated station for the next operation.

The crystal bar is a raw material for manufacturing a crystal silicon battery in a photovoltaic module. The photovoltaic module is a device capable of converting solar energy into electric energy, and can provide the electric energy for equipment and facilities in a use area so as to meet the electricity demand of production and life. Photovoltaic power generation has the following advantages: the principle is simple, no mechanical movement, no fuel consumption, no emission of any substance including greenhouse gases, no noise and no pollution; the energy conversion process is simple, is the conversion from light energy to electric energy directly, has no intermediate process (such as conversion of heat energy to mechanical energy, conversion of mechanical energy to electromagnetic energy and the like) and mechanical movement, and has no mechanical abrasion; the fuel is not used, any substances including greenhouse gases and other waste gases are not discharged, air is not polluted, noise is not generated, and the environment is protected; no mechanical transmission part, simple operation and maintenance and stable and reliable operation.

The specific principle of photovoltaic power generation is that when sunlight irradiates a crystalline silicon cell of a photovoltaic module, the crystalline silicon cell absorbs solar energy and generates current.

As shown in fig. 1-4, an embodiment of the present application provides a crystal bar transport vehicle 10, where the crystal bar transport vehicle 10 includes a carrying device 1 and an auxiliary device 2, and the carrying device 1 is provided with a carrying area 11 for carrying a crystal bar 20; the auxiliary device 2 comprises a connecting part 21 and a cooling part 22, the connecting part 21 is connected to the carrying device 1, the connecting part 21 is provided with a first connecting part 211 higher than the carrying area 11, the cooling part 22 is connected with the first connecting part 211, and the cooling part 22 is used for cooling the crystal bars 20 in the carrying area 11.

The crystal bar transport vehicle 10 is applied to the production process of crystal bars 20. After the crystal pulling process is completed, the high temperature ingot 20 is produced, and the ingot 20 is transported to a designated station by the ingot transport vehicle 10. The process of placing the ingot 20 on the ingot transport vehicle 10 is specifically to place the ingot 20 on the loading area 11 of the loading device 1. The carrying device 1 can be a carrying rack or a carrying stage and the like; the carrying area 11 may be a groove, which has a certain limiting effect on the crystal bar 20, so as to prevent the crystal bar 20 from rolling and separating from the carrying device 1 during transportation. The cross-sectional shape of the grooves may be semicircular or triangular. The bottom of the groove can be provided with a plurality of ventilation holes, which is beneficial to heat dissipation of the crystal bar 20.

In the process of transporting the crystal bar 20, as the cooling component 22 is connected to the connecting component 21 connected with the carrying device 1, the crystal bar 20 in the carrying area 11 can be cooled by the cooling component 22, so that the cooling speed of the crystal bar 20 is accelerated, the cooling efficiency is improved, the shaping speed of the crystal bar 20 is further improved, and the circulation efficiency of the crystal bar 20 is improved.

Specifically, the crystal bar transport vehicle 10 further includes a temperature detecting device (not shown in the figure), where the temperature detecting device may be connected to the first connecting portion 211, and the temperature detecting device is configured to detect an actual temperature of the crystal bar 20 in real time, and transmit the detected actual temperature of the crystal bar 20 to the control center, where the control center may calculate a cooling speed of the crystal bar 20, analyze whether the cooling speed of the crystal bar 20 meets a requirement, and if the cooling speed meets the requirement, maintain an existing operation condition of the cooling component 22, and if the cooling component 22 does not meet the requirement, adjust the operation condition of the cooling component 22, for example, when the cooling component 22 is a fan, adjust a rotation speed of a blade of the fan, so that the temperature of the crystal bar 20 meets a requirement when the crystal bar 20 is transported to a specified station. The temperature detection means may in particular be a temperature sensor.

In addition, as shown in fig. 1, the cooling members 22 may be plural, and the plural cooling members 22 are connected to the first connection portion 211, and the plural cooling members 22 cool the ingot 20 at the same time.

As shown in fig. 1, the ingot transport vehicle 10 further includes a support member 3 and a roller 4, wherein one end of the support member 3 is connected with the carrying device 1, the other end is connected with the roller 4, and the roller 4 can roll on the ground. The ingot transport vehicle 10 may be manually moved. Alternatively, the ingot transport vehicle 10 is provided with a driving device, a sensing device, and the like, and automatically travels along a set route.

In order to facilitate the disassembly and assembly of the cooling member 22, the cooling member 22 may be detachably connected to the first connection portion 211.

The connecting member 21 further includes a second connecting portion 212, and the first connecting portion 211 is detachably connected to the carrying device 1 through the second connecting portion 212, so as to facilitate the dismounting operation of the auxiliary device 2. For example, when the ingot 20 is not placed in the loading area 11, the auxiliary device 2 does not need to be connected with the loading device 1, so that interference to the placement of the ingot 20 is prevented; when the crystal bar 20 is placed in the carrying area 11, the auxiliary device 2 can be connected with the carrying device 1, so that the cooling component 22 cools the crystal bar 20 in the carrying area 11; after the ingot 20 is transported to the designated station, the auxiliary device 2 is removed and the ingot 20 is removed.

The second connection portion 212 may be screwed or clamped with the carrying device 1.

In one embodiment, the cooling element 22 has an air outlet, all or a portion of which is directed toward the load carrying area 11.

The cooling component 22 may include a heat exchanger and an air outlet fan, and the cooling medium may flow through the heat exchanger and exchange heat with air outside the heat exchanger, so that the air is cooled, and under the action of the air outlet fan, the cooled air is blown to the carrying area 11 through the air outlet, so that the crystal bar 20 in the carrying area 11 is cooled. The cooling medium may be a medium substance in various heat engines for energy conversion, which absorbs heat of the cooled object at low temperature and then transfers the heat to cooling water or air at higher temperature, and may be ammonia (code: R717), freon-12 (code: R12), tetrafluoroethane (code: R134 a), etc.

Alternatively, the cooling member 22 is a fan, and the blades of the fan rotate to force convection of air in the opposite region of the air outlet, so that the heat transfer rate between the air and the ingot 20 is increased, and further, the ingot 20 emits more heat.

The air outlet may be all or part of the air outlet may face the loading area 11, so long as the temperature of the crystal rod 20 in the loading area 11 can be reduced.

In order to facilitate the manufacture and installation of the cooling member 22 and to reduce the cost of the cooling member 22, the cooling member 22 is a fan. The fan converts electric energy into air kinetic energy, adopts a forced convection mode (fluid circularly flows under the action of external force) to force air to convect in the front area of the fan, so that the heat transfer rate between the air and the crystal bar 20 is improved, and further, the crystal bar 20 emits more heat, and the purpose of cooling is achieved.

The air outlet of the fan may be directed wholly or partly towards the loading area 11.

The side of the first connection portion 211 facing the carrying area 11 may be provided with a receiving groove, and the fan is mounted in the receiving groove and is fixed to the first connection portion 211 by a screw connection.

In order to improve the cooling efficiency of the ingot 20, the number of fans may be set to be plural. The plurality of fans may be uniformly distributed in the first connection portion 211.

The fan can adopt a small-sized fan, so that the occupied space is saved.

More specifically, the fan is provided with a rechargeable battery, the first connection portion 211 is provided with a charging portion 213, the charging portion 213 is electrically connected with the rechargeable battery, and the charging portion 213 can be electrically connected with an external power source to charge the rechargeable battery.

The rechargeable battery can provide electric energy for the operation of the fan, so that the fan is not required to be connected with a power line in the operation process, interference of the power line on running of the crystal bar transport vehicle 10 is avoided, and convenience is brought to running of the crystal bar transport vehicle 10.

When the rechargeable battery needs to be charged, the external power supply can be electrically connected with the charging part 213, so as to charge the rechargeable battery, thereby being convenient and fast. The charging unit 213 may be a socket or a wireless charging device.

In order to reduce the risk of injury to personnel caused by contact of the personnel with the ingot 20 during transportation of the ingot 20, in this embodiment, the first connecting portion 211 surrounds the loading area 11.

After the crystal bar 20 is placed in the carrying area 11, the first connecting portion 211 surrounds a part of the outer surface of the crystal bar 20 along the circumferential direction of the crystal bar 20, which is equivalent to separating the part of the outer surface of the crystal bar 20 from the outside, so that the protection effect on personnel can be achieved, and the risk of personnel injury caused by the contact of the personnel and the crystal bar 20 is reduced.

Specifically, along the length direction X of the carrying area 11, the projection of the first connection portion 211 may be arc-shaped or square-shaped. As shown in the example, the first connection portion 211 is an arc-shaped bracket, and the arc-shaped bracket is erected above the carrying area 11; when the ingot 20 is placed in the loading area 11, the arcuate supports surround a portion of the outer surface of the ingot 20 in the circumferential direction of the ingot 20.

In this embodiment, the first connecting portion 211 is of an arc shape or a square shape, and is simple in structure and convenient to manufacture.

The material of the first connection portion 211 may be a plastic material or a metal material. For example, the first connection portion 211 is a polypropylene bracket or a polyurethane bracket or a steel bracket or an iron bracket or an aluminum alloy bracket.

In some embodiments, the side of the first connection portion 211 facing the loading area 11 is provided with a flexible buffer layer.

In the transportation process of the crystal bar 20, the possibility that the crystal bar 20 is touched with the first connecting portion 211 exists, in order to prevent the crystal bar 20 from being damaged, a flexible buffer layer is arranged, the crystal bar 20 can be touched with the flexible buffer layer, the protection effect on the crystal bar 20 is achieved, and the damage risk of the crystal bar 20 is reduced.

The flexible buffer layer may be a flexible plastic material, such as silica gel. The flexible buffer layer may be specifically adhered to the inner surface of the first connection part 211.

To improve the connection stability of the connection member 21 and the carrier device 1, the carrier device 1 includes mounting portions located on both sides of the width direction Y of the carrier region 11, and both ends of the first connection portion 211 in the circumferential direction thereof are connected to the mounting portions by the second connection portions 212, respectively.

One of the second connecting portion 212 and the mounting portion may be a buckle, and the other may be a slot, where the buckle is cooperatively connected with the slot. Alternatively, one of the second connection portion 212 and the mounting portion is an insertion portion, and the other is a mounting groove, and the insertion portion is inserted into the mounting groove so that the second connection portion 212 and the mounting portion are connected.

In order to improve the cooling uniformity of the entire ingot 20, as shown in fig. 1, a plurality of auxiliary devices 2 are provided, and the plurality of auxiliary devices 2 are arranged along the longitudinal direction X of the loading area 11.

Each auxiliary device 2 is provided with a cooling component 22, so that each auxiliary device 2 can cool each position of the crystal bar 20 simultaneously, and the overall cooling uniformity of the crystal bar 20 is improved.

Further, the first connection portion 211 of each auxiliary device 2 surrounds a part of the outer surface of the ingot 20 along the circumferential direction of the ingot 20 to isolate the ingot 20 from the outside, further reducing the risk of injury to personnel caused by touching the ingot 20 with personnel.

In other embodiments, as shown in fig. 4, only one auxiliary device 2 may be provided, where the first connection portion 211 extends along the length direction X of the carrying area 11, and the first connection portion 211 covers the carrying area 11 entirely; after the crystal bar 20 is placed in the carrying area 11, the part of the crystal bar 20 above the carrying area 11 is covered by the first connecting part 211, so that the protection of the crystal bar 20 and personnel is realized, the personnel is prevented from being scalded, and the crystal bar 20 collides with; the first connection portion 211 is connected with a plurality of cooling components 22, and the plurality of cooling components 22 are uniformly arranged on the outer surface of the crystal bar 20 so as to cool each position of the crystal bar 20 and speed up cooling efficiency.

According to some embodiments, after the ingot 20 is manufactured, a process of transporting the ingot 20 using the ingot transporting vehicle 10 is described as follows:

the height Wen Jingbang 20 is placed in the carrying area 11 of the carrying device 1 by using a manual or machine, then the auxiliary devices 2 are respectively connected to corresponding positions of the carrying device 1, and then the fans are turned on to enable the fans to simultaneously discharge air so as to cool the crystal bars 20 placed in the carrying area 11, so that the crystal bars 20 can be rapidly cooled and shaped; the crystal bar 20 is cooled, and meanwhile, the crystal bar transport vehicle 10 automatically runs according to a set route according to related instructions of a control center; in the running process of the crystal bar transport vehicle 10, the temperature detection device detects the actual temperature of the crystal bar 20 in real time, the detected actual temperature of the crystal bar 20 is transmitted to the control center, the control center can calculate the cooling speed of the crystal bar 20 and analyze whether the cooling speed of the crystal bar 20 meets the requirement, if the cooling speed meets the requirement, the existing blade rotating speed of the fan is maintained, and if the cooling speed does not meet the requirement, the blade rotating speed of the fan is regulated, so that the actual temperature of the crystal bar 20 meets the requirement when the crystal bar 20 is transported to a designated station.

When the crystal bar 20 is transported to a designated station, the crystal bar transport vehicle 10 stops running, the fans are turned off, and the auxiliary devices 2 are detached respectively; after all the auxiliary devices 2 are removed, the ingot 20 is removed manually or by machine.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the same, but rather, various modifications and variations may be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a crystal bar transport vechicle which characterized in that, crystal bar transport vechicle includes:

the device comprises a carrying device (1), wherein the carrying device (1) is provided with a carrying area (11) for carrying the crystal bar (20);

auxiliary device (2), auxiliary device (2) include connecting component (21) and cooling part (22), connecting component (21) connect in carry thing device (1), connecting component (21) are equipped with be higher than carry first connecting portion (211) of thing region (11), cooling part (22) with first connecting portion (211) are connected, cooling part (22) are used for right crystal bar (20) cooling in carrying thing region (11).

2. Ingot transport vehicle according to claim 1, characterized in that the cooling element (22) has an air outlet, all or part of which is directed towards the loading area (11).

3. The ingot transport vehicle as set forth in claim 1, wherein the cooling component (22) is a fan.

4. A crystal bar transport vehicle according to claim 3, characterized in that the fan is provided with a rechargeable battery, the first connection part (211) is provided with a charging part (213), the charging part (213) is electrically connected with the rechargeable battery, and the charging part (213) can be electrically connected with an external power source to charge the rechargeable battery.

5. Ingot transport vehicle according to claim 1, characterized in that the first connection (211) encloses the loading area (11).

6. The ingot carrier vehicle as claimed in claim 5, characterized in that the projection of the first connection part (211) is arc-shaped along the length of the loading area (11).

7. The ingot carrier vehicle as claimed in claim 5, characterized in that a side of the first connection part (211) facing the loading area (11) is provided with a flexible buffer layer.

8. The ingot carrier vehicle according to claim 5, wherein the loading device (1) includes mounting portions located on both sides in the width direction of the loading area (11), the connecting member (21) further includes second connecting portions (212), and both ends of the first connecting portion (211) in the circumferential direction thereof are connected to the mounting portions through the second connecting portions (212), respectively.

9. The ingot carrier vehicle according to any one of claims 1-8, characterized in that the connecting part (21) further comprises a second connecting portion (212), through which second connecting portion (212) the first connecting portion (211) is detachably connected with the loading device (1).

10. Ingot transport vehicle according to any of claims 1-8, characterized in that the auxiliary device (2) is provided in a plurality, a plurality of auxiliary devices (2) being arranged in the length direction of the loading area (11).