tips to maximize crushing efficiency - pit & quarry : pit & quarry

tips to maximize crushing efficiency - pit & quarry : pit & quarry

To apply what this means to your crusher, operations produce the exact sizes in the reduction process that their market demands. In the past, quarries produced a range of single-size aggregate products up to 40 mm in size.

In practice, many jaw crushers are not fed to their designed capacity. This is because the subsequent processing plant does not have sufficient capacity to handle the volume of material that would be produced if the jaw crusher was working to capacity.

If you seek fewer fines, trickle feeding material into the jaw crusher could achieve this. But this would have an adverse effect on particle shape, and it also reduces throughput capacity, hindering the crushers efficiency.

Ideally, the feed rate should not be switched from choke to non-choke, as this can cause problems downstream at the secondary processing plant. In practice, many jaw crushers are fed in this intermittent fashion due to gaps in the delivery of feed material from the quarry.

The reduction ratio is then calculated by comparing the input feed size passing 80 percent versus the discharge size that passes 80 percent. The finer the closed-side setting, the greater the proportion of fines produced.

The closed-side setting of a jaw crusher helps determine the nip angle within a chamber, typically 19 to 23 degrees. Too large of an angle causes boiling in the crushing chamber. This is where the jaw plates cannot grip onto the rock, and it keeps slipping up and down, avoiding being crushed. The nip angle gets flatter as the machine is set tighter.

The settings on a jaw crusher are designed to produce material ideal for secondary crushing. The best particle shape is typically found in material that is about the same size as the closed-side setting.

Smaller sizes will contain a higher proportion of elongated particles because they have passed through the crusher without being touched. Larger sizes may also contain a higher proportion of elongated particles because they are further from the closed-side setting. This can cause bridging issues in downstream machines.

It is critical that a cone-type crusher be choke fed to produce the best product shape and quality. It is not as important in a jaw, as material is not generally stockpiled after the jaw. Because the cone is part of the secondary and tertiary stations, particle shape assisted by a choke-fed chamber is important because finished products are created in these stages.

Choke feeding is important for cone crushers because it maintains a good particle shape by facilitating an inter-particle crushing action. Trickle feeding is not the best option because it increases the proportion of flaky material in the crusher product, hindering its efficiency.

It is a good rule to maintain about 10 to 15 percent of material finer than the closed-side setting in the feed to assist crushing action. More than 10 to 15 percent will likely cause ring bounce due to the pressures in the chamber.

Its important to find the right liner for the feed gradation and desired product. If the liner is too large, feed material will drop too far in the chamber before being crushed. Too fine of a liner will prevent material from entering the chamber at all.

Monitoring the crushing force as registered through the load on the crusher motors, as well as the pressure on the hydraulic mantle adjustment mechanism, will give forewarning of crusher packing problems before they affect your efficiency.

Try to match the closed-side setting of the crusher to the top size of the product to be produced. If closing the circuit at 1 in. to produce a 1-in.-minus product, set the crusher at or near 1 in. or slightly below.

The initial impact is responsible for more than 60 percent of the crushing action, with the remainder made up of impact against an adjustable breaker bar and a small amount of inter-particle collision.

This is why it is vitally important that the feed arrangement to an impact crusher ensures an even distribution of feed material across the full width of the rotor. This will allow for even distribution of energy into the feed material and uniform wear patterns, ensuring consistent product gradation and power consumption.

Slower rotor speeds can be used as a means of reducing fines but may result in a product with more oversize or return than is desired. Slower rotor speeds are preferable as a means of minimizing the wear on crusher components, as well as for achieving less fines production and optimal product size.

The product grading from an impact crusher will change throughout the life of the wear parts, particularly the impact hammers or blow bars. As the profile of the hammer changes with increased wear, the product grading becomes coarser. Many modern impact crusher installations have a variable speed drive arrangement that allows an increase in the rotor speed to compensate for wear on the impact hammers.

In many impact crushers, a third curtain or crushing chamber can be added to increase reduction in every pass through the machine. This can be important in finer product applications where the third chamber can provide the desired output gradation. A third chamber that increases the reduction will also increase the power needs and, normally, the wear cost.

One tip to consider: Decreasing the gap between the hammers and impact curtain increases particle retention in the chamber. This increases the size reduction ratio, but it also reduces efficiency throughput capacity and increases fines production.

Follow the steps outlined in this article to achieve the best crushing efficiency for jaw, cone, gyratory and impact crushers and to ultimately increase profits and reduce fines production. By taking these steps, youre reducing the amount fines produced and adding dollars to your pocket.

tips for maintaining efficiency in crushing circuits - quarry

tips for maintaining efficiency in crushing circuits - quarry

Efficiency can be defined by the ratio of work done by a machine to the energy supplied to it. To apply what this means to your crusher, in your reduction process you are producing exactly the sizes your market is demanding.

In the past, quarries produced a range of single-size aggregate products up to 40mm in size. However, the trend for highly specified aggregate has meant products have become increasingly finer. Currently, many quarries do not produce significant quantities of aggregate coarser than 20mm; it is not unusual for material coarser than 10mm to be stockpiled for further crushing.

A jaw crusher is a compression-type of crusher. Material is reduced by squeezing the feed material between a moving piece of steel and a stationary piece. The setting or the space between those two pieces of steel controls the discharge size. The tighter the setting, the smaller the output size and the lower the throughput capacity. Jaw crushers are mainly used in primary crushing; they are rarely used as a secondary crusher.

As compression crusher, jaws generally produce the coarsest material because they break the rock by the natural inherent lines of weakness. A jaw crusher can be an excellent primary crusher when used to prepare rock for subsequent processing stages such as washing, classifying or a secondary crusher.

Try to choke-feed any compression-type crusher. Remember, we are using gravity and the weight of the material to push or force material through the chamber. Since in a compression machine the material breaks to fill the air pockets or voids in the chamber, a non-choke chamber will produce a slabbier output than a choke-fed chamber.

Jaw crushers are routinely choke-fed, as this maximises production capacity and ensures particles are uniformly broken. This promotes stone-on-stone crushing, which breaks up flaky or slabbier particles. If you are seeking fewer fines, trickle-feeding material into the jaw crusher could achieve this; however, this would have an adverse effect on particle shape and would also reduce throughput capacity, hindering the crushers efficiency.

Ideally, the feed rate should not be switched from choke to non-choke, as this would cause problems downstream at the secondary processing plant. In practice, many jaw crushers are fed in this intermittent fashion due to gaps in the delivery of feed material from the quarry. Jaw crusher feed should be pre-screened using a grizzly screen prior to crushing, to remove material finer than the closed side setting (CSS).

In practice, many jaw crushers are not fed to their design capacity; this is because the subsequent processing plant does not have sufficient capacity to handle the volume of material that would be produced if the jaw crusher were working to capacity.

Ideally, the reduction ratio of a jaw crusher should be 6:1. There are different ways to calculate reduction ratio, but the best way is something called the P80 factor. The reduction ratio is then calculated by comparing the input feed size passing 80 per cent versus the discharge size that passes 80 per cent. The finer the CSS, the greater the proportion of fines produced. The CSS of a jaw crusher helps determine the nip angle within a chamber, typically 19 to 23 degrees. Too large an angle causes boiling in the crushing chamber; this is where the jaw plates cannot grip onto the rock and it keeps slipping up and down, avoiding being crushed. The nip angle gets flatter as the machine is set tighter.

The settings on a jaw crusher are designed to produce material ideal for secondary crushing. The best particle shape is typically found in material about the same size as the CSS. Smaller sizes will contain a higher proportion of elongated particles because they have passed through the crusher without being touched. Larger sizes may also contain a higher proportion of elongated particles, as they are further from the CSS, which can cause bridging issues in downstream machines. The bottom line is that the best particle shape and performance comes from a choke-fed chamber.

Cone crushers and gyratory crushers are also compression-type machines that crush material between moving and stationary pieces of steel. The setting between the two pieces of steel controls the output. Though the chamber is round in shape, the moving piece of steel is not meant to rotate. Instead a wedge is driven around to create compression on one side of the chamber and discharge opening on the opposite side.

Cone crushers are used in secondary and tertiary roles as an alternative to impact crushers, when shape is an important requirement but the proportion of fines produced needs to be minimised. Even though the reduction in fines produced may be only a few percentage points, this could represent a significant amount of material in a large operation and, ultimately, increase an operations bottom line and profitability.

Increasing the CSS in an attempt to reduce the amount of fines produced may have the opposite effect; it may lead to a greater proportion of oversized material, which would need re-crushing in the remaining crushing circuits and would ultimately lead to a higher proportion of fines being produced. The further in the crushing process, the greater the amount of fines produced.

It is critical that a cone-type crusher be choke-fed to produce the best product shape and quality. It is not as important in a jaw, as material is not generally stockpiled after the jaw. Since the cone is in the secondary and tertiary stations, particle shape assisted by a choke-fed chamber is important, as it creates finished products in these stages.

Uniform distribution of feed material around the cone crusher inlet is a good practice. This allows production of a consistent product, as well as efficient, reliable operation of the crusher. Choke-feeding is important for cone crushers because it maintains a good particle shape by facilitating an inter-particle crushing action. Trickle feeding is not the best option because it increases the proportion of flaky material in the crusher product, hindering its efficiency.

It is a good rule to maintain about 10 to 15 per cent of material finer than the CSS in the feed to assist crushing action. More than 10 to 15 per cent will likely cause ring bounce due to the pressures in the chamber.

Pre-screening of the feed to remove the fines, especially in tertiary crushing, is a good practice; it helps to avoid packing of material in the chamber while maintaining an efficient, effective crushing action and increasing your crusher efficiency.

The liner profiles are designed for a range of product sizes, from extra coarse (EC) to extra fine (EF). The EF liner profile will result in the highest fines proportion for a given cone crusher. It is important to find the right liner for the feed gradation and desired product. If the liner is too large, feed material will drop too far in the chamber before being crushed. Too fine a liner will prevent material from entering the chamber at all.

Monitoring the crushing force as registered through the load on the crusher motors, as well as the pressure on the hydraulic mantle adjustment mechanism, will give forewarning of crusher packing problems before they affect your efficiency.

The finer the CSS, the greater the proportion of fines produced. The finer setting also lowers throughput volume. It is important to match the CSS of the crusher to the top size of the product to be produced. If the circuit is being closed at 25mm (1) to produce a 25mm minus product, the crusher should be set at, near or slightly below 25mm.

An impact crusher uses mass and velocity to break down feed material. First, the feed material is reduced as it enters the crusher with the rotating blow bars or hammers in the rotor. The secondary breakage occurs as the material is accelerated into the stationary aprons or breaker plates. Impact crushers tend to be used where shape is a critical requirement and the feed material is not very abrasive. The crushing action of an impact crusher breaks a rock along natural cleavage planes, giving rise to better product quality in terms of shape. The quality of these products makes them ideal for use in highly specified road, stone and concrete aggregate applications.

Establishing the proper rotational speed of the blow bars or hammers is critical for efficient reduction and production. Also, the angle of the feed plate that introduces the feed material to the rotor assists in the efficiency of the machine. Improper rotor penetration will result in decreased performance.

Size reduction in an impact crusher relies on energy being conveyed into the rock from the rotor, and it begins with your feed. The initial impact is responsible for more than 60 per cent of the crushing action, with the remainder made up of impact against an adjustable breaker bar and a small amount of inter-particle collision. This is why it is vitally important that the feed arrangement to an impact crusher ensures an even distribution of feed material across the full width of the rotor. This will allow for even distribution of energy into the feed material and uniform wear patterns, ensuring consistent product gradation and power consumption.

Establishing the proper rotational speed of the blow bars or hammers is critical for efficient reduction and production. Also, the angle of the feed plate that introduces feed material to the rotor assists in the efficiency of the machine. Improper rotor penetration will result in decreased performance.

Size reduction and, ultimately, the crusher setting are directly proportional to the rotor speed; it largely dictates how many fines are produced. Slower rotor speeds can be used as a means of reducing fines, but may result in a product with more oversize or return than is wanted. Slower rotor speeds are preferable as a means of minimising the wear on crusher components and for achieving less fines production and optimal product size.

The product grading from an impact crusher will change throughout the life of the wear parts, particularly the impact hammers or blowbars. As the profile of the hammer changes with increased wear, the product grading becomes coarser. Many modern impact crusher installations have a variable speed drive arrangement that allows an increase in the rotor speed to compensate for wear on the impact hammers.

In many impact crushers, a third curtain or crushing chamber can be added to increase reduction in every pass through the machine. This can be important in finer product applications, where the third chamber can provide the desired output gradation. A third chamber that increases the reduction will also increase the power needs and, normally, the wear cost.

Decreasing the gap between the hammers and impact curtain increases particle retention in the chamber. This increases the size reduction ratio; however, it also reduces efficiency throughput capacity and increases fines production.

Crushing efficiency begins with common crusher knowledge. Once you have a machine a jaw, cone/gyratory or impact crusher how you feed it and how you set it will affect its efficiency. By taking many of the steps outlined above to achieve the best crushing outcome, producers can reduce the amount of fines they produce and save more dollars for their pockets.

jaw crusher - sciencedirect

jaw crusher - sciencedirect

Designs of different types of jaw crushers such as Blake, Dodge with single and double toggles used for initial comminution of minerals, as received from mines, are described in detail. The method of calculating operating variables such as the critical speed, toggle frequency and throw and power consumptions are explained and illustrated with practical examples with solutions. Further, inter-related mathematical relations between variables such as critical speed, toggle throw, frequencies of operation and crusher power and throughput, as derived by different workers, are indicated.

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