PL216674B1 - System of automatic sprinklers of dust sources on the mine transport routes - Google Patents

Description

Description of the invention

The subject of the invention is a system for automatic sprinkling of dust sources on mine transport routes, in particular at overfills of mining conveyors.

There are a number of concepts and design solutions for sprinkling devices designed to combat dust on mine transfer roads and discharge points. They differ from each other in the type of applied impulse switching on the sprinkling system of these devices. The origin of the pulses may be related to the movement of the conveyor belt, the load on the belt or the thickness of the transported layer of spoil on the conveyor belt. It can also be an electrical signal transmitted simultaneously with the start of the conveyor's driving motors or an impulse transmitted depending on the humidity of the material transported on the belt.

An automatic sprinkling device for pouring is known from the patent description PL 65061. This solution consists in the fact that the excavated material transported by the conveyor sets the lever of the pump-valve unit in swinging motion, and thus causes the reciprocating movement of the pump piston and pumping oil under the cut-off valve diaphragm. As a result, the water supply to the spray nozzles arranged above the conveyor is opened. Stopping the conveyor belt or lack of excavated material on it immobilizes the device's lever, which in turn cuts off the water supply to the nozzles.

Another concept of the automatic spraying system, known from the patent description PL 201305, is a solution that uses an electric control unit operating on the basis of impulses received from sensors of belt motion, spoil accumulation and spoil moisture. Above the dust source, there are water nozzles, which are powered by solenoid valves controlled by signals from the control unit.

There is also known from the patent description PL 129 022 a method of dust suppression, especially on conveyor heaps and dumps, whereby the stream of spoil is additionally sprinkled from below in the area of the falling spoil between the feeding device and the device collecting the spoil.

In addition, a solution used in British mines is known from the prospectuses of Conflow Ltd., having a conveyor belt motion sensor in the form of a contact wheel with a loaded belt, transmitting the drive to the oil pump, which forcing oil under the piston coupled with the water valve causes the valve to open and supply water to spray nozzles. When the conveyor is in motion and the belt is empty (not loaded), it does not make contact with the pulley and the water valve remains closed. Likewise, when the belt is stopped, the drive pulley remains stationary and the sprinkler system is turned off.

A significant disadvantage of all known concepts and devices is that the sources of the pulses generating the signals for their activation do not take into account the actual state of the amount of dust present in the area where this dust is present, for example in the area of the dump. Due to the above, the sprinkling system often works without a justified need, which significantly worsens the parameters of the transported output. Excessive moistening of the transported output causes troublesome sticking of the conveying belt, necessitating the use of appropriate belt cleaning devices, and seriously hinders the process of coal classification and enrichment in processing plants.

The system of automatic sprinkling of dust sources according to the invention has a dust sensor in the area of the dust source, the input of which is connected to the circuit transmitting electrical signals from the sensor for starting the drive or moving the conveyor belt to the digital control panel, while the output is connected by a wire transmitting electrical control pulses to the digital control panel control. The control panel, in turn, is connected by wires transmitting electric control pulses to electro-distributors located in the branches of the spraying medium flow, through which the spraying medium flows to the sets of spraying batteries located in the dust area.

At the same time, water pressure-controlled water check valves and air check valves are located in the path of media flow to the spray faucet sets.

In addition, a pressure threshold sensor is connected to the central water line supplying the system, which is connected by a control line to the digital control unit.

It is important to equip the system with a device for cleaning the optical system of the dust sensor. Preferably, the cleaning device is in the form of a nozzle. This device has an electro-distributor on the supply line for the cleaning medium, which is connected with a control line to a digital control unit.

It is important if there is a non-return valve controlled by the pressure of this medium in the path of the medium flowing to the cleaning device.

Moreover, in the case of air-water spraying, it is preferable that the spraying battery packs are equipped with air-water spraying nozzles.

The subject of the invention is shown in the embodiment in the drawing, in which Fig. 1 shows a diagram of the automatic air-water spraying system for the discharge, and Fig. 2 schematically shows the automatic spraying system for the discharge using only water.

The system includes: a digital control unit 1, a sensor 11 for starting the drive or moving the conveyor belt and a dust sensor 4, called a dust meter, which is located in the place of the highest dustiness, i.e. in the dumping area. On the other hand, above the dumping site, in the place where the spoil is transferred from the feeding conveyor 6 to the collecting conveyor 7, there are sets of sprinkling batteries A and B, in which nozzles or sprinkling devices are located.

The automatic sprinkler overflow system shown in Fig. 1 of the drawing has two cycles of the sprinkling media - the water circuit shown in solid lines and the compressed air circuit shown in dotted lines. The control cables are shown in dashed lines. This system includes: electro-distributors 2a, 2b located in the sprinkling medium flow branches and the electro-distributor 2c located in the compressed air circuit, check valves 3a, 3b located in the sprinkling medium flow branches and check valves 3c, 3d and 3e located in the compressed air flow circuit. The check valves 3a and 3c are controlled by the pressure of the spraying medium coming from the electro-distributor 2a, and the check valves 3b and 3d are controlled by the pressure of the spraying medium coming from the electro-distributor 2b, and the check valve 3e by the compressed air coming from the electro-distributor 2c.

The electro-distributor 2a cooperates with the sprinkling circuit of the spraying batteries set A, the electro-distributor 2b with the sprinkling circuit of the sprinkler batteries set B, and the electro-distributor 2c with the circulation of compressed air cleaning the dust sensor 4. The non-return valve 3a is installed in the sprinkling circuit of the sprinkler batteries set A, and the check valve 3b in the spray circuit of the spray battery pack B.

The check valve 3c cooperates with the spraying circuit of the spraying battery set A, the non-return valve 3d with the spraying circuit of the spraying battery set B, and the non-return valve 3e is located in the cleaning circuit of the dust sensor 4 installed in the overfill area. Moreover, in each branch of the media supplying the sets of A and B spraying batteries there are check valves that are opened by the pressure of the flowing medium. In the water circuit, these are check valves 9a and 9b, located on the medium flow path from the check valves 3a, 3b to the sets of spraying batteries A and B, and in the air circuit these are check valves 9a and 9d, located on the medium flow path from the check valves 3c. , 3d for A and B spray sets.

The system is also equipped with a device 10 for cleaning the optical system of the dust sensor 4, preferably in the form of an air nozzle, to which the air supply is controlled by an electro-distributor 2c and a non-return valve 3e.

There is also a threshold water pressure sensor 5 in the water circuit, and moreover, the media supply to the system includes elements not shown or not marked in the drawing, such as filters, reduction valves and safety valves, which do not affect the essence of the invention.

The sensor 11 for starting the drive or moving the conveyor belt is connected by a wire transmitting an electric signal to the digital control unit 1 and to the dust sensor 4. The dust sensor 4 is connected by an electric control cable to the digital control unit 1. At the same time, the digital control unit 1 is connected to the control wires with electro-distributors 2a, 2b and 2c and a water pressure sensor 5.

The flow path of the media in the system is as follows: Water from the fire-fighting line is led into the system through the pressure reducing valve and filter, and is then divided into four branches, two of which are supply branches that deliver water to the A and B sprinkler sets via check valves 3a and 3b, and the other two supply water to manifolds 2a and 2b controlled by electric pulses. From the distributors 2a and 2b, the water is directed to the control branch of the check valves 3a and 3b, causing them to open. This allows flow

The return valves 9a, 9b for the two-fluid spraying nozzles 8 in the sets of spraying batteries A and B are installed in these branches, and the flow of water under pressure through the electro-distributors 2a and 2b causes also opening check valves 3c and 3d located in the compressed air flow path. Compressed air, supplied to the system through a filter, is divided into three branches. Two of them supply compressed air to check valves 3c and 3d, through which, after prior opening of these valves with water pressure, the compressed air flows through the non-return valves 9c and 9d to the two-fluid spraying nozzles 8. The third branch supplies compressed air to the electro-electric valve. separator 2c and after flowing out of it, it opens the check valve 3e with its pressure, allowing air to flow to the nozzle 10 cleaning the optics of the dust sensor 4.

The principle of operation of the automatic air-water sprinkling system is presented below.

After starting the drive or conveyor belt, the signal from the sensor 11 is transmitted to the digital control unit 1 and to the dust sensor 4, causing it to switch on and start automatic transmission of its signals to the digital control unit 1. The control unit 1 analyzes the received signal in terms of the measured value dust and, depending on it, impulses are sent to the appropriate electro-distributors 2a and / or 2b, which, after override, cause the media to flow to set sets of spray batteries A and / or B equipped with spraying nozzles 8, after prior opening of appropriate check valves 3a and 3c and / or 3b and 3d. Depending on the amount of dust, one or two sets of spraying batteries A and / or B are supplied with media. If the set of spraying batteries A does not reduce the dustiness, it is automatically replaced by a set of spraying batteries B with a greater number of spraying nozzles. 8, or both sets of spray batteries A and B are turned on simultaneously.

The automatic sprinkler system is automatically turned off when the water pressure in the circuit disappears, and the signal to the control unit 1 is transmitted by the threshold sensor 5.

However, when cleaning the dust sensor 4 with an air nozzle, this sensor is turned off by a signal transmitted from the digital control unit 1.

Fig. 2 of the drawing shows a simplified version of the system. In this version, only a water circuit was used to power the sprinkler battery sets at the transfer point. One-way water spraying nozzles or water spraying devices with injection of ambient air, giving a limited effect of air-water spraying can be used here.

The water flow path in this system is as follows: the water supplied to the system through the reduction valve and the filter is divided into four branches, which lead it to electro-distributors 2a and 2b controlled by electric impulses from the digital control unit 1 and to check valves 3a and 3b enabling its flow , excluding electro-distributors 2a and 2b. Then, from the check valves 3a and 3b, the water flows respectively through the check valves 9a and 9b to two sets of spraying batteries A and B equipped with spraying devices or water nozzles 12.

The method of controlling the system in this embodiment is identical to the system shown in Fig. 1.

The automatic sprinkler sprinkler system according to the invention, both in the air-water and water-only versions, can be simplified when only one set of spraying batteries A or B is used for sprinkling the discharge or other source of dust on the transport roads. Then only one power supply will be used in air and water or only water, as in the second embodiment. Then the number of electro-distributors and controlled valves in these circuits will also be reduced.

The system in any of the embodiments may be simplified by using electro-distributors 2a, 2b and 2c with sufficient flow capacity to supply water and compressed air to the sets of sprinkler batteries A and B, as well as the device 10. The controllable check valves 3a can then be eliminated. , 3b, 3c, 3d and 3e.

Claims (6)

Patent claims 1.A system of automatic sprinkling of dust sources on mine transport routes, especially at the hoppers of mining conveyors, by means of sprinkling devices or nozzles, which in the branches of the sprinkling medium flow have devices controlled by electrical impulses coming from the control unit, and also has a control unit cooperating with control unit a sensor for starting the drive or movement of the conveyor belt, characterized in that it has a dust sensor (4) located in the area of the dust source, the input of which is connected to the circuit transmitting electrical signals from the sensor (11) for starting the drive or moving the conveyor belt to the digital control center (1), and the output is connected by a wire transmitting electrical control pulses to the digital control unit (1), which in turn is connected by wires transmitting electrical control pulses to electro-distributors (2a) and (2b) located in the branches of the sprinkling medium flow, behind by means of which the flow of the sprinkling medium to the sets of sprinkler batteries (A) and / or (B) is effected. 2. The system according to claim The method of claim 1, characterized in that there are water pressure-operated check valves (3a) and (3b) and air check valves (3c) and (3d) in the path of media flow to the sets of sprinkler batteries (A) and / or (B). 3. The system according to p. A pressure threshold sensor (5) is connected to the central water supply line to the system, which is connected by a control line to the digital control unit (1). 4. The system according to p. A device according to claim 1, characterized in that it has a device (10) for cleaning the optical system of the dust sensor (4), preferably in the form of an air nozzle, which on the way of feeding the cleaning medium has an electro-distributor (2c) connected by a control line to the digital control unit (1) . 5. The system according to p. The method of claim 4, characterized in that a non-return valve (3e) is provided in the path of the medium supplying the device (10) for cleaning the optical system of the dust sensor (4). 6. The system according to p. A method as claimed in claim 1, characterized in that it is equipped with air-water spray nozzles (8).