UA141208U - Brush collector - Google Patents

Abstract

The proposed utility model relates to electrical engineering, in particular to brush collectors with dust removal used for a generator with a vertical axis of rotation, for example, hydrogenerators of power plants. The essence of the utility model is that the current-collecting element contains at least one stationary current-carrying traverse (1), in which the front end surface (11) is equidistant to the outer surface of a horizontally located working ring (2) of a generator with a vertical axis of rotation, while on the upper surface of the traverse (12) there are brush holders (3) with brushes (4) installed in them, which interact with the said outer surface of the working ring (2), and under the lower surface of the traverse (13), the dust collecting tray (5) is located so that its front end face (51) protrudes in front of the front end surface of the traverse (11) as a result of which the inner cavity (52) of the dust collecting tray (5) is located under the gap (6) formed between the outer surface of the working ring (2) and the front end surface of the traverse (11), while from the said inner cavity (52) of the dust collecting tray (5) through at least one air The dust extraction pipe (7) removes dust evenly along the entire length of the inner cavity (52). The technical result of the proposed utility model is to ensure the intake of dust along the entire perimeter of the brushes operation area without gaps and "blind" zones.

Description

The proposed useful model belongs to electrical engineering, in particular to brush current collectors with dust removal, which are used for a generator with a vertical axis of rotation, such as a hydro generator of power plants.

During the operation of brush current collectors, the working surface of the brush rubs against the working ring of the hydrogen generator. As a result of this, the formation of dust occurs, which can accumulate in the area of current collection, which can lead to an electrical breakdown and, as a result, to an emergency situation. Therefore, in the process of operation of generators, brush current collectors with dust removal are used, for example, see MoMoe patents 058829761, 5І1356083, ов1005433, 59293967, SHО52106842 56707217, 0О057915782. The essence of which, in general, boils down to the fact that in the contact zone of the brush and the working ring, organized air removal is carried out, which removes dust particles formed as a result of brush abrasion from the current collection zone. The design feature of most known technical solutions is that they are used for hydro generators with a horizontal axis of rotation, the number of which is greater than generators with a vertical axis of rotation - hydro generators of power plants.

Since the arrangement of the working ring in the horizontal plane leads to the fact that in the process of contact of the working surface of the brush with the working surface of the ring on the formed part of the dust, the tangential force of inertia and gravitational force acts on the formed part of the dust, which leads to the formation of the resulting gravitational data forces. Since the magnitude and size of the formed part is an uncontrollable quantity, it is clear that the resulting forces will be different and therefore the organization of "point" air removal from each brush does not ensure complete removal of dust and local removal has a significant drawback - a small radius of action of the discharge formed in the area of air removal into the air outlet of the air outlet.

As for the technical solution according to the Mo patent 58829761, the essence of which is to close the brush holders and brushes in a protective cover, into which dust enters and then remove it from the cover, this technical solution does not take into account the effective resultant force, which does not ensure effective dust removal, as well as when using this technical solution, there are difficulties in arranging a large number of brush holders in a straight line and adjusting the distance between the brushes of the brush holders and the curved outer surface of the generator ring, and this does not allow to ensure the complete consumption of the brush.

The task of the proposed useful model is to ensure effective removal of dust from the current collection zone for generators with a vertical axis of rotation, for example, for hydro generators of power plants.

Also, the task of the proposed useful model is to increase the probability of a larger amount of dust removal.

Also, the task of the proposed useful model is to create a brush current collector with dust removal for generators with a vertical axis of rotation.

Other tasks and advantages of the proposed useful model will be considered below as the description and accompanying drawings are presented.

A known brush current collector containing current collection elements with dust removal, according to the proposed model, the current collection element contains at least one fixed current-conducting traverse, in which the front end surface is equidistant from the outer surface of the horizontally located working ring of the generator with a vertical axis of rotation, while on the upper surface of the traverses are located brush holders with brushes installed in them, which interact with the mentioned outer surface of the working ring, and under the lower surface of the traverse, the dust-collecting tray is located so that its front end side protrudes in front of the front end surface of the traverse, as a result of which the inner cavity of the dust-collecting tray is located under the gap formed between the outer surface of the working ring and the front end surface of the traverse, while from the mentioned inner cavity of the dust collecting tray, through at least one air outlet, dust removal is carried out dust evenly along the entire length of the internal cavity.

Also, according to the proposed useful model, the dust removal air nozzles are connected evenly along the entire length of the dust collecting tray, and at the outlet, the dust removal nozzles are connected to the collective dust removal collector fixed on the traverse.

Also, according to the proposed useful model, the longitudinal profile of the collector is equidistant to the front surface of the traverse.

Also, according to the proposed useful model, a removable plug is made in the end surface of the collector.

Also, according to the proposed useful model, the rear end wall and the side end walls of the dust collecting tray are made higher than its front end wall and at the same time they are adjacent to the lower surface of the traverse, as a result of which a gap is formed between the lower surface of the traverse and the upper surface of the front end wall of the dust collector tray

Also, according to the proposed useful model, dust deflectors are located between the brush holders, along the front end surface of the traverse.

Also, according to the proposed useful model, the traverse is fixed on a vertical support on one of the sides with the possibility of its rotation.

Also, according to the proposed utility model, the collection collector is adjacent to the sunbed opposite the vertical support through a flexible connection.

When considering the essence and examples of the implementation of a useful model, it should also be borne in mind that the generator contains two identical groups of brush current collectors of positive and negative polarities. Therefore, everything that will be described below belongs equally to each of them.

A narrow terminology is used when considering examples of implementation of the proposed useful model. However, the proposed useful model is not limited to accepted terms and it should be kept in mind that each such term covers all equivalent solutions that work in a similar way and are used to solve the same tasks.

The essence of a useful model is explained by the drawing, where:

Fig. 1 - shows a schematic general view of the installation of a brush current collector on a horizontally located working ring of the generator.

Fig. 2- shows a fragmentary general view from the side of the upper surface of the traverse.

Fig. 3 - shows a fragmentary general view from the side of the lower surface of the traverse.

Fig. 4 - the depicted fragment in the section of the brush current collector on the horizontally located working ring of the generator.

The list of positions shown in the above figures 1-4: 1- conductive traverse; 11- the front end surface of the current-carrying traverse; 12 - the upper surface of the current-carrying traverse;

From 13 - the lower surface of the current-carrying traverse; 2 - the working ring of the generator with a vertical axis of rotation;

C - brush holder; 4 - brush; 5 - dust collecting tray;

C5 51 - the front end side of the dust collecting tray; 52 - the inner cavity of the dust-catching tray;

Bz - the rear end wall of the dust collecting tray;

Ba - side end walls of the dust-catching tray; b - the gap formed between the outer surface of the working ring 2 and the front end surface of the traverse 11; 7 - dust removal air nozzle; 8 - collective collector; 8: - a gasket through which the collecting manifold 8 is attached to the traverse 1; 9 - removable plug; 10 - slotted gap formed between the lower surface of the traverse 1z and the upper surface of the front end wall of the dust-catching tray 5:; 11 - dust-reflecting shields located between brush holders 3; 12 - vertical support of traverse 2; 13 - a bed, to which the collective collector 8 is attached; 14 - flexible connection.

The essence of the proposed useful model is that the particles of graphite dust separated from the brush 4 fall into the discharge zone, which occurs in the gap 6 as a result of the removal of dust from the internal cavity 52 through the air nozzle of the dust removal 7.

Since the front end surface of the traverse 11 is equidistant from the outer surface of the working ring 2, this allows for the formation of a single size of the gap 6 along the entire length of the front end surface of the traverse 1, and this allows the maximum use of the brush 4 and ensures the maximum possible wear of it, simplifies the adjustment of the brush holders Z and their adjustment for activation in case of wear of the brush 4, and also allows to form and maintain the amount of uniform rarefaction in the gap 6 along its entire length. At the same time, in the event of a decrease in the amount of discharge or in the event of a fan failure (not shown in the drawing), dust particles still enter the inner cavity 52 of the dust collecting tray 5, because the inner cavity 52 is located under the gap 6 and the front end closest to the working ring 2 the side of the dust collecting tray 5: brought under the working ring 2, which is also an advantage of the proposed utility model. At the same time, it should be noted separately that the design of hydro generators of power plants can lead to the fact that transformer oil can get into the area of the pantograph, which can, mixing with dust, get into the inner cavity 52 of the dust collecting tray 5, which is an advantage of a useful model.

The uniform adjacency of the dust removal air nozzles 7 to the collective collector 8, which adjoins the traverse 1, allows to simplify the installation of the dust removal nozzles 7, because their length and standard dimensions will be the same, which allows to form a uniform dust removal along the entire length of the cavity 52. Also, the attachment of the collective collector 8 to traverse 1 allows you to protect service personnel from contact voltage, and also simplifies maintenance of the contact pantograph, because in the event of a technological or emergency situation, traverse 1 is returned together with the collecting collector 8 as a result of fastening the traverse on the vertical support 12, which does not lead to the necessary disassembly costs , assembly of the dust removal system.

Also, the mounting of the collective collector 8 on the traverse 1 increases the reliability and tightness of the removal of the dust-air mixture from the internal cavity 5", as it ensures a rigid attachment and supply of the dust removal nozzles 7, while their length is minimal.

The use of collective collectors 8 minimizes aerodynamic resistance and improves the efficiency of dust removal.

An example of implementation

Assembly and installation of a brush current collector with dust removal on the working ring of 2 generators with a vertical axis of rotation is carried out. Why are the traverses 1 fixed on the vertical support 12 to ensure their rotation. On the upper surface of the traverse 1, there are brush holders C with brushes 4, and under the lower surface of the traverse 12, there is a dust-catching tray 5 so that its front surface 51 protrudes in front of the front end surface of the traverse 11 and goes under the working ring 2. Front surfaces 11 and 51 arc-shaped under the outer surface of the working ring 2. As a result of the installation of traverse 1, surface 1, and 5x equidistant outer surface of the working ring 2. Therefore, it is formed

From the gap 6 of equal width along the entire length of the front end surface of the traverse 11.

In the lower surface 51 of the dust-collecting tray 5, holes are made along its entire length, to which the nozzles of the dust collector 7 are connected at the input, which are connected to the collection collector 8 at the output.

The collector 8 is fixed on the traverse 1 from the rear end side of it and is fixed through the insulating gasket 8: for electrical safety. At the same time, the collective collector 8 has an arc-shaped profile similar to the outer working surface of the working ring 2, as a result of which the nozzles of the dust collector 7 have the same length and aerodynamic resistance. A removable plug 9 is installed on one end surface of the collective collector 8, with the help of which it is possible to carry out technological cleaning of the inner surface of the collective collector 8 from dust, which can form growths as a result of leakage of transformer oil of the generator with a vertical axis of rotation. On the opposite end side, the collective collector 8 is connected to the couch 13, which is connected to the fan unit (not shown in the drawing) and the air dust removal unit (not shown in the drawing), which is diverted from the inner cavity 52 of the dust collecting tray 5. The couch 13 is placed opposite the vertical support 12, on which the traverse 1 rotates, while the collector assembly 8 is connected to the bed 13 through a flexible connection 14. As a result of the removal of the traverse 1, there is an opportunity for a technological inspection of the outer working surface of the working ring 2, brush holders 3, brushes 4, and the dust collecting tray 5, as well as for cleaning the collective collectors 8 and also to ensure the replacement of traverses 1 without dismantling the brush current collector with dust removal. All this reduces generator downtime, reduces maintenance costs and simplifies work with the brush pantograph according to the proposed useful model.

During the operation of the generator (not shown in the drawing) with a vertical axis of rotation, the working ring 2 rotates, and this leads to friction of the brushes 4 on the outer surface of the working ring 2, which is accompanied by the formation of finely dispersed graphite dust, which enters the inner cavity 52 of the dust collector through the gap 6 tray 5. From the internal cavity 52, the dust is removed through the air nozzles of the dust removal 7 into the collection collector 8, from which it is removed into the couch 13. In the future, the air is dedusted with its further removal into the atmosphere.

In the case of an emergency stop of the fan unit or its periodic shutdown to save electricity or to carry out a technological inspection, dust through the gap 6 still enters the internal cavity 52, which is located under the gap. Since the size of the part,

formed, the amount is uncontrolled, then large parts are reflected from the dust deflectors 11 and also fall through the gap 6 into the internal cavity 5".

The long developed inner surface of 52 dust-catching trays 5 ensures dust collection along the entire perimeter of the work area of brushes 4, without gaps and "blind" zones, which is a significant advantage of the proposed useful model.

Since the assembled collectors 8 protrude as much as possible outside the current-conducting traverse 1, they are easily accessible for human touch. Therefore, the collective collectors 8 are electrically isolated from the traverse 1 using insulating pads 81.

The proposed useful model is not limited to the above examples of its implementation. This description contains information that is necessary and sufficient for a clear understanding of the essence of the proposed useful model. Information that is obvious to specialists in this field of technology and that did not contribute to a better understanding of the essence of the proposed useful model, was not given in this description.

It is clear that when using the proposed useful model, dust can be removed from the inner cavity 52 through the dust removal air nozzle 7, for example, the dust removal nozzle 7 can be located in the inner cavity 52 along its entire length, while holes for dust removal are made in the nozzle. Another example, the lower surface of the dust-collecting tray 5 is made in the form of a conical funnel, in the lower part of which the dust removal nozzle 7 is attached. But in this case, it is difficult to ensure uniform rarefaction over the entire size of the gap 6.

The execution of the rear end wall 5z and the side end walls 55 of the dust collecting tray 5 above the front end wall 5: and at the same time they adjoin the lower surface of the traverse 5, as a result of which a slit gap 10 is formed between the lower surface of the traverse 5 and the upper surface of the front end wall of the dust collecting tray 51. This leads to the fact that the intake of air into the internal cavity 52 is carried out only from the front end surface of the conductive traverse 11, which allows to reduce the volume of air that is removed, and, therefore, to use less powerful fans, which leads to the saving of electrical energy on their work, which is also an advantage of the proposed useful model.

The technical result of the proposed useful model is the provision of dust collection by

From the entire perimeter of the brush work area without gaps and "blind" zones.

Claims (8)

USEFUL MODEL FORMULA 1. A brush current collector containing current collection elements with dust removal, which is characterized by the fact that the current collection element contains at least one fixed current-conducting traverse (1), in which the front end surface (11) is equidistant from the outer surface of the horizontally located working ring (2) of the generator with a vertical axis of rotation, while on the upper surface of the traverse (12) there are brush holders (3) with brushes (4) installed in them, which interact with the mentioned outer surface of the working ring (2), and under the lower surface of the traverse (13) there is a dust collecting tray (5) ) is located so that its front end side (12) protrudes in front of the front end surface of the traverse (13), as a result of which the inner cavity (52) of the dust collecting tray (5) is located under the gap (b) formed between the outer surface of the working ring (2) ) and the front end surface of the traverse (1), while from the mentioned inner cavity (52) of the dust-collecting tray (5) through at least one dust removal air nozzle (7) produces dust removal evenly along the entire length of the internal cavity (552). 2. Brush current collector according to claim 1, which is characterized by the fact that the dust removal air nozzles (7) adjoin evenly along the entire length of the dust collecting tray (5), and at the outlet, the dust removal nozzles (7) adjoin the collection collector (8) from the dust removal fixed on traverse (1). 3. Brush current collector according to claim 2, which is characterized by the fact that the longitudinal profile of the collective collector (8) is equidistant from the front surface of the traverse (11). 4. Brush current collector according to claim 2, which is characterized by the fact that a removable plug (9) is made in the end surface of the collective collector (8). 5. Brush current collector according to claim 1, which is characterized by the fact that the rear end wall (5z) and the side end walls (54) of the dust collecting tray (5) are made higher than the front end wall (51) and at the same time they adjoin the lower surface of the traverse (13 ), as a result of which a slit gap (10) is formed between the lower surface of the traverse (13) and the upper surface of the front 60 end wall of the dust collecting tray (51). 6. The brush current collector according to claim 1, which is characterized by the fact that between the brush holders (3) along the front end surface of the traverse (11) there are dust deflecting brushes (11). 7. Brush current collector according to claim 1, which is characterized by the fact that the collective collector is adjacent to the couch (13) opposite the vertical support (12) through a flexible connection (14). 8. A brush current collector according to any of claims 1-7, which is characterized by the fact that the traverse (1) on one of the sides is fixed on a vertical support (12) with the possibility of its rotation. KIN V nn ro a Ne i r She v a S poten ef z y uky she VE B Y ia Ku KO ey nan Y She vm, ik KI p DE ro Pes i KM I sn She a v y; de B t I1g Zhe Zh NN yah ge HNN U u TE S ya vii ya shi ty ke SHE SHY kish zh chen noya i nashi ko I: Ye vych ia y ta zhk ia i p shchyh ska a a o o I OO KY Kk in Zhsha Nezh In I GA ish uorie- p nan NN NN Y r y s an eeUYNyNNeinya et A o rya ZD: KV la nie MK NI Y o spos Vil in i i: MY eh IY M ok nn vanny she M z ze Shi NN VN se! at 4 p.m. Mon Fig. 1 and in KL Te SN that shock y Kann DT zv KM kt : and 4. і ni o vy shi OV che di Ya nyu and N ra, OV PI always -Y : she В SHO | i I Shi oo ve A u Ya : U I hi po aa Z A su vo VAZ V I : : don Sho sha: Z yi di so ! i i te Sn che i ch re i I SHE ney rya She sa ai i Z V 4 v N i : du Z i i. I Zh K sh-y ky she vin Yaeh ; OV VE. I. CHAY Fig. 2