阅读说明：本技术 铜冶炼渣包保温及冷却装置 (Copper smelting slag ladle heat preservation and cooling device ) 是由 姚书俊 张志国 刘长青 韩清清 郑春雨 刘国林 金泽智 于 2021-08-23 设计创作，主要内容包括：本发明属于冶金领域,具体涉及一种铜冶炼渣包保温及冷却装置,包括用于容纳渣包的渣包槽和与渣包槽相适应的槽盖,所述渣包槽的侧壁上设有进水口、出水口和溢流口,溢流口的高度高于进水口和出水口。采用上述方案,渣包槽不仅起到保温效果,而且可以阻挡雨雪进入渣包,从而避免了雨雪天气造成的炉渣迅速降温,这样炉渣有足够的时间进行含铜颗粒的生长,为后续炉渣的选矿处理做好准备；并且,雨水与炉渣不接触,缓冷场地的雨水可以直接进入城市与水管道,无需进行雨污分流；缓冷阶段过后,向渣包槽中持续通入冷却水,冷却水是从进水口进入、溢流口流出,与渣包中的炉渣不接触,避免出现放炮现象,整个装置安全、环保。(The invention belongs to the field of metallurgy, and particularly relates to a copper smelting slag ladle heat preservation and cooling device which comprises a slag ladle groove for accommodating a slag ladle and a groove cover matched with the slag ladle groove, wherein a water inlet, a water outlet and an overflow port are formed in the side wall of the slag ladle groove, and the height of the overflow port is higher than that of the water inlet and the water outlet. By adopting the scheme, the slag ladle groove not only has the heat preservation effect, but also can prevent rain and snow from entering the slag ladle, so that the slag is prevented from being rapidly cooled in the rain and snow weather, the slag has enough time to grow copper-containing particles, and the preparation is made for the subsequent mineral processing of the slag; in addition, the rainwater is not contacted with the slag, the rainwater in the slow cooling field can directly enter the city and a water pipeline, and rainwater and sewage distribution is not needed; after the slow cooling stage, cooling water is continuously introduced into the slag ladle groove, enters from the water inlet and flows out from the overflow port, and is not in contact with slag in the slag ladle, so that the blasting phenomenon is avoided, and the whole device is safe and environment-friendly.)

1. The utility model provides a copper smelting cinder ladle heat preservation and cooling device which characterized in that: including sediment package groove (10) that is used for holding sediment package (A) and capping (20) that suits with sediment package groove, be equipped with water inlet (11), delivery port (12) and overflow mouth (13) on the lateral wall of sediment package groove (10), the height of overflow mouth (13) is higher than water inlet (11) and delivery port (12).

2. The copper smelting slag ladle heat preservation and cooling device of claim 1, characterized in that: the height of the groove edge of the slag ladle groove (10) is lower than that of the lifting lug of the slag ladle (A).

3. The copper smelting slag ladle heat preservation and cooling device of claim 1, characterized in that: the outer groove edge and the inner groove edge of the slag ladle groove (10) have a height difference, and the cover edge of the groove cover (20) is matched with the groove edge of the slag ladle groove (10).

4. The copper smelting slag ladle heat preservation and cooling device of claim 1, characterized in that: the water inlet (11) is communicated with a cooling water source, and the cooling water continuously enters the slag ladle groove (10) and flows out of the overflow port (13) to enter the heat collecting system.

Technical Field

The invention belongs to the field of metallurgy, and particularly relates to a copper smelting slag ladle heat preservation and cooling device.

Background

Copper smelting slag is generally treated by a method of firstly cooling and then dressing so as to further recover copper in the slag. The cooling process is divided into two stages: the first stage is slow cooling, the slag bag filled with molten slag (the temperature is higher than 1300 ℃) is placed in a slag slow cooling field for 2-8 hours firstly until the temperature of the slag reaches about 1050 ℃, cooling measures such as spraying and the like are not needed in the process, the slag is required to be cooled as slowly as possible, and therefore, the copper-containing small particle materials in the slag have more time to grow into large particles so as to be beneficial to subsequent ore dressing; and the second stage is spray cooling, wherein the slag in the slag ladle is sprayed and cooled, and after the slag is cooled to a safe temperature, the slag in the slag ladle is poured out and sent to a mineral separation system for treatment.

However, the above solutions have many drawbacks:

firstly, the slag ladle is placed in the open air and can be cooled rapidly in the first cooling stage of the slag ladle when meeting rain and snow weather, and actually the growth effect of copper-containing particles in the first cooling stage does not exist, which is equivalent to directly entering the second stage of spray cooling;

secondly, two continuous processes of slag ladle slow cooling and spray cooling generally require about 65 hours, so that slag slow cooling fields of general copper smelting plants are large, the total amount of rainwater is large in rainy days, the slag slow cooling fields cannot realize complete rainwater and sewage distribution, and the environmental protection risk is large;

and in the spray cooling stage, cold water is in direct contact with high-temperature furnace slag and can generate slag packages to explode when encountering slag with matte, so that the production safety problem exists for workers, the spraying device and other operation equipment can be damaged by explosion, the furnace slag splashes far, the site cleaning cost is high, and time and labor are wasted.

Disclosure of Invention

The invention aims to provide a copper smelting slag ladle heat preservation and cooling device, which can ensure smooth slow cooling of slag, prolong the slow cooling time, avoid blasting phenomenon caused by slag spray cooling, and is safer and more environment-friendly.

In order to achieve the purpose, the invention adopts the technical scheme that: the utility model provides a sediment package heat preservation and cooling device are smelted to copper, is including the sediment package groove that is used for holding the sediment package and the capping that suits with sediment package groove, be equipped with water inlet, delivery port and overflow mouth on the lateral wall in sediment package groove, the height of overflow mouth is higher than water inlet and delivery port.

By adopting the scheme, after the copper smelting furnace slag is loaded into the slag ladle, the slag ladle is firstly placed into the empty slag ladle groove, and the groove cover is covered, so that the slag ladle groove not only has the heat preservation effect, but also can prevent rain and snow from entering the slag ladle, thereby avoiding the rapid cooling of the furnace slag caused by rain and snow weather, ensuring that the furnace slag has enough time to grow copper-containing particles and preparing for the subsequent mineral processing of the furnace slag; in addition, the rainwater is not contacted with the slag, the rainwater in the slow cooling field can directly enter the city and a water pipeline, and rainwater and sewage distribution is not needed; after the slow cooling stage, cooling water is continuously introduced into the slag ladle groove, enters from the water inlet and flows out from the overflow port, and is not in contact with slag in the slag ladle, so that the blasting phenomenon is avoided, and the whole device is safe and environment-friendly.

Drawings

FIG. 1 is a schematic view of a copper smelting slag ladle heat preservation and cooling device of the present invention.

Detailed Description

The technical scheme of the invention is further detailed in the following with reference to the accompanying drawings.

The utility model provides a copper smelting cinder ladle heat preservation and cooling device, is including the cinder ladle groove 10 that is used for holding cinder ladle A and the capping 20 that suits with the cinder ladle groove, be equipped with water inlet 11, delivery port 12 and overflow mouth 13 on the lateral wall of cinder ladle groove 10, overflow mouth 13 highly is higher than water inlet 11 and delivery port 12.

The slag ladle groove 10 is empty initially, and after the slag ladle A filled with slag is put into the slag ladle groove 10, the cover groove cover 20 is covered. After the slag ladle is kept warm for a certain time (after the temperature of the slag is reduced to below 1050 ℃), a water outlet 12 of a slag ladle groove 10 is closed, water is continuously injected from a water inlet 11 to cool the slag ladle A, cooling water is continuously discharged from an overflow port 13, after the slag ladle is cooled to a safe temperature, the cooling water injection is stopped, the water outlet 12 of the device is opened simultaneously, the water in the slag ladle groove 10 is drained completely, the cooled slag ladle is hung out and dumped, in the whole process, the slow cooling stage is prolonged, rain and snow are prevented from entering the groove cover, no waste water is generated in the cooling stage, the blasting phenomenon is avoided, and the slag ladle furnace is beneficial to subsequent mineral separation and is safe and environment-friendly.

Preferably, the height of the groove edge of the slag ladle groove 10 is lower than that of the lifting lug of the slag ladle A. The slag ladle is placed into the slag ladle groove 10 by using a hoisting device, in order to enable the slag ladle groove 10 to avoid slag ladle lifting lugs and the hoisting device, the height of the groove edge of the slag ladle groove 10 is lower than that of the slag ladle lifting lugs, as shown in figure 1, after the slag ladle is placed into the slag ladle groove, a groove cover is covered, the groove cover is also in an inverted groove shape, and the sum of the heights of the slag ladle groove and the groove cover is slightly higher than that of the slag ladle.

The outer groove edge and the inner groove edge of the slag ladle groove 10 have a height difference, and the cover edge of the groove cover 20 is matched with the groove edge of the slag ladle groove 10. The outer part of the groove edge of the slag ladle groove 10 is preferably high, the inner part of the groove edge of the corresponding groove cover 20 is preferably high, the inner part of the cover edge is low, the slag ladle groove and the groove cover are required to be used at high temperature, so the slag ladle groove and the groove cover are made of steel plates, the size and the weight of the slag ladle groove and the cover are large, the groove cover can be covered on the slag ladle groove after being lifted by a hoisting device, the edges of the slag ladle groove and the cover are designed to be mutually corresponding in height difference, namely the groove edge is designed to be an inclined plane, and even if the upper position and the lower position of the groove edge slightly deviate, the slag ladle groove and the cover can be finally aligned under the guidance of the inclined plane of the groove edge, so that the upper and the lower tight thread joint can be realized.

The water inlet 11 is communicated with a cooling water source, and the cooling water continuously enters the slag ladle groove 10 and flows out from the overflow port 13 to enter the heat collecting system. Because the slag temperature is quite high, most of heat is absorbed by cooling water, water can be introduced into other processes needing heat so as to reduce energy loss, a heat collecting system can be a system needing heat such as a boiler and the like, and the heat can be returned to a cooling water source for recycling after the water temperature is reduced. Compared with the prior art, the method does not produce waste water, and realizes the recycling of energy.

The technical scheme of the invention can also reduce the cost:

1. by taking a certain copper smelting plant as an example, the weather of rain and snow in the local area accounts for 18% of the whole year, the slow cooling effect of the 18% of the time can be improved by adopting the method, 200 ten thousand tons of slag are processed annually, the amount of 18% of slag is 36 ten thousand tons, the ore dressing tailings of each ton of slag are reduced by 0.01%, and the economic benefit is increased by 180 ten thousand yuan annually by calculating the income of 5 yuan per ton.

2. And the slag ladle is prevented from blasting in a slow cooling place, so that the safety of staff is facilitated, and the maintenance loss caused by blasting is reduced. The slag ladle is blasted in a slow cooling field, and the personal safety of operation and point inspection staff can be threatened. Moreover, the cleaning and maintenance cost is about 1.0 ten thousand yuan when blasting is generated once, so that 2 times of calculation is avoided every year, and the loss is reduced and is 2.0 ten thousand yuan.

3. The rain and sewage separation of the cooling water and the rainwater is completely realized. After the slag ladle cooling water recycling device is adopted, slag ladle cooling water is collected into a pool through a sealed pipeline and is returned for reuse after being cooled. And the pollution of the cooling water by the ring set is avoided. At present conventional slow cooling mode, cooling water and sediment contact, and partial arsenic and copper have been dissolved in the cooling water, and continuous heavy rain weather causes cooling water and rainwater to mix, and the water after the mixture contains arsenic and copper and exceeds standard, needs the collection to handle. By adopting the technical scheme of the invention, the cooling water is not in contact with site rainwater and can be separately collected and treated, thereby thoroughly solving the problem of rainwater and sewage separation.