RU2099526C1 - Method for mining of gently dipping contiguous potassium beds - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: with leading extraction of the first stage rooms, rigid interroom pillar is formed in lower bed, then it is relieved by extraction of mineral in upper bed by rooms with formation of yielding pillars. Then in zone of relief of lower bed, secondary rooms are extracted in rigid interroom pillars. In this case yielding pillars are formed between rooms of the second stage. EFFECT: higher efficiency. 1 dwg

Description

 The invention relates to the mining industry and can be used in the development of close seams, including outburst hazardous.

There is a method of developing powerful mineral deposits with a chamber development system, including the extraction of minerals with the left pillars and breaking minerals using the effect of oncoming radially directed emission to the center of the camera [1]
The disadvantage of this method is the low extraction of minerals.

Closest to the proposed technical solution is a method of developing close seams, including the extraction of minerals by cameras while leaving compliant interchamber pillars and advancing mining of the upper reservoir, with cameras that are located on the same axis as the interchamber pillars of the lower reservoir, and the width of the executive cameras take no less than the width of the inter-chamber pillars [2]
The disadvantage of this method is the significant development time of the lower layer, which does not exclude the possibility of loading it as a result of the termination of the destructive action of the overlying layer and the loss of stability of interchamber pillars during the technological period.

 The technical result of the invention is to increase the development efficiency by providing in-line excavation of adjacent formations without reducing the safety of work.

 The specified technical result is achieved by the fact that the mining of one of the mineral strata is carried out ahead of time, the minerals are mined by the cameras and malleable interchamber pillars are formed, while the mining of minerals in the lower stratum is carried out by two burst cameras, when the first stage chambers are advanced mining, hard interchamber pillars are formed in the lower layer, after which the lower layer is unloaded by excavation of minerals in the upper layer by cameras with the formation of malleable pillars, and then in the unloading zone of the lower layer, secondary chambers are excavated in rigid interchamber pillars, while compliant pillars are drawn between the second stage chambers.

 The previously indicated technical result was not achieved by mining the secondary chambers of the underlying formation in the unloading zone of the underlying formation at the stage of progressive creep of the pillars of the upper formation.

 The drawing shows a scheme for mining adjacent layers.

 The method is as follows.

 Initially, the underlying formation is practiced, the loading coefficient of inter-chamber pillars with a minimum of 0.2 0.3. At a given loading coefficient, their deformation and fracture practically do not occur.

 After that, the overlying formation is mined with parameters at which the loading coefficient of the interchamber pillars is 0.7 0.9, i.e., the pillars are deformed and collapsed after mining the chambers within 2 - 2.5 months. The effect of unloading the underlying formation appears at a distance of 50 to 100 m from the front of the treatment works of the underlying formation.

 Using the effect of unloading the underlying reservoir, additional secondary chambers are drilled in the interchamber pillars to ensure safe mining during technological time.

Consider the implementation of the method on a specific example. Two adjacent formations with a thickness of 3.2 m are subject _to mining; m _n 3.7 m; the distance between the layers h 5-6 m

 Initially, the lower stratum is mined by chambers 1 with a width of 6.1 m and an inter-chamber pillar with a width of 9.5 m (pillar loading coefficient with ≅ 0.3). After mining the underlying formation, the overlying formation is chambered by chambers 3 3.2 m wide, leaving inter-chamber pillars 2.0 m (the degree of loading of pillars C is approximately 0.7, i.e. leaving pliable pillars).

 At a distance of 50 to 100 m from the front of the treatment works in the direction of the worked out space on the overlying formation, the underlying formation is unloaded from mountain traffic. The rock pressure drops sharply, reaches 0.5 γH, and favorable conditions are created for the safe mining of the secondary chambers 2 of the underlying formation located in the places of the primary “hard” interchamber pillars. At the same time, mining is carried out with the provision of malleable pillars 4 of 1.7 m in size, which ensure the stability of the chambers for the technological time of mining these chambers.

 If necessary (in order to reduce the subsidence of the earth's surface and the safety of the airborne surface), it is possible to use the bookmark of the worked-out space with a completeness of filling, which ensures the permissible subsidence of the earth's surface.

Using the proposed method allows you to:
to increase the extraction of minerals in comparison with the prototype by reducing the width of the inter-chamber pillars during the passage of the secondary chambers along the underlying layer;
increase work safety, as development of the underlying reservoir is carried out in the discharge zone from rock pressure;
increase the manufacturability of mining, as mining of the secondary chambers depends only on the speed of moving the treatment work on the overlying formation, i.e., it is possible to stop mining the secondary chambers if it stops on the upper layer and resume mining during subsequent mining of the upper layer;
carry out detailed geological exploration of industrial reservoirs from primary treatment chambers of the lower reservoir.

Claims (1)

 A method for the development of shallow adjoining potash beds, including advanced mining of one of the beds, mining of minerals with cameras and the formation of compliant interchamber pillars, characterized in that the mining of minerals in the lower layer is carried out by two-stage cameras, with advanced mining of the first-stage chambers, rigid interchamber pillars are formed in the lower layer, after which the lower layer is unloaded by excavation of minerals in the upper layer by chambers with the formation of malleability x pillars, and then in the discharge zone of the lower layer, secondary chambers are excavated in rigid interchamber pillars, while compliant pillars are drawn between the second stage chambers.