CS256498B1 - Ventilating device for high-power electromotor in overfloor box variant - Google Patents

Abstract

The device solves the structural arrangement the front of the electric motor housing including power cabinets located below supply lines, in connection with ventilation and machine cooling, in front the motor housing is in front of the winding faces a separating partition and two to it and to the front wall of the cabinet with adjacent side partitions the vertical channel in which they pass from the power supply cabinet to the stator power supply jumper winding water, while venting the pipe is its own through the inlet opening to the bottom the front of the electric motor housing. The essence is that against the entrance hole the vent pipe is the bottom the first lateral partitions are provided with a through through an opening to whose edges it is vertical from the inside channel adjacent open front side of box-shaped olons of insulating material, whose open underside, 1e results in a power supply cabinet, v whereby heating elements are optionally installed.

Description

The invention relates to a ventilating device of high-performance electric motors in a above-ground box version.

The prior art devices for ventilation of said electric motors consist of a supply duct through which air is supplied to the lower parts of their housing, usually from the side thereof, and a ventilation unit located at the top of the housing through which air is vented to the outside. The opening of the ventilation openings is remotely controlled by electromagnetic or pneumatic valves. The parts of the electric motor inside the cabinet must be designed so that the entire space can be properly ventilated before starting the machine. Nevertheless, each electric motor has its own specific space, which is difficult to ventilate and often expensive. The problem of thorough ventilation of the whole machine comes to the fore especially when the electric motor operates in an environment with explosive gases heavier than air. Therefore, in electric motors installed in these conditions, attention is focused in particular on spaces which are lower than the inlet opening of their ventilation ducts, such as the internal spaces of the power supply enclosures to which the cables for supplying the stator windings are brought.

This problem is solved by the ventilating device of the high-performance electric motor in the above-ground box version according to the invention, under which at least one front side is a prismatic power supply box which is spatially connected to the front space of the electric motor box. Part of this front space is separated by the walls of a vertical quadrilateral channel formed by a separating partition in front of the winding faces and two to it and to the front wall of the cabinet by adjacent side bulkheads in which

256 498 come from the power supply housing of the electrical passport forming the jumpers between the power supply and the stator winding. In the lower part of the front space there is an inlet opening of the ventilation pipe from the side of the box. It is an object of the invention that, opposite the vent pipe inlet, the lower part of the opposite first side wall is provided with a through hole, the edges of which have an open front side of a box of insulating material adjacent to the inside of the vertical channel. For ease of manufacture and assembly, it is advantageous if the space shield is composed of two parts which are detachably connected in a vertical plane parallel to the front wall of the electric motor housing. If necessary, heating elements are built into the power supply box.

The ventilation device according to the invention ensures perfect ventilation of even the lowest-lying, i.e., under-floor, spaces of electric motors operating in environments with explosive gases heavier than air, thus eliminating the risk of explosion. The design and positioning of the air curtain regulating the air flow improves the cooling of its inlets even in the working mode of the electric motor. The installation of the heating elements in the power supply cabinet enables the blowing of the electrical conducting parts with warm air, which is advantageous especially for electric motors placed in unheated areas, where during their shutdown time their insulation may dew condense. This measure thus achieves its drying.

In the accompanying drawing, an example of a ventilation device according to the invention is shown, in which FIG. 1 is a cross-sectional side view of the front part of an electric motor housing, and FIG. 2 is the front view of the same section in three vertical sections.

An exemplary venting device is part of the construction of a high-performance electric motor in a above-ground box design. The electric motor has two stator windings connected to stars, each of which is led to one front. Since both sides of the electric motor are mirrored, it will be described below

256 498 only one of them. The phase terminals of the stator winding are connected to one side of the stud forming the current windings of the measuring transformers 10 incorporated in the partition 8, which is located in front of the winding cells. By means of a separating partition 8 and two side walls 6, 7 adjacent to the front wall of the box 6, a vertical channel 15 is formed in the front floor of the box 7, which is spatially connected to a prismatic supply box 3 fixed in the concrete base by fastening elements 14. and detachably airtightly coupled to the housing b of the electric motor. Inside the power supply housing 3, three horizontal phase busses 12 are fixed parallel to its front wall, to which power cables 11 and one end of the power supply jumpers 9 formed by electrical passports which vertically extend through the vertical channel 13 and whose other ends are fixed therein At the bottom of the power supply housing 3, two heating elements 5 are installed parallel to the buses 12. In the lower corner of the side wall of the electric motor housing there is an inlet opening 2 of the ventilation duct opening into the front space of the housing. Opposite this, an aperture of approximately rectangular shape is formed at the bottom of the opposite first side partition 6, to the edges of which a front open side of a box-shaped shutter 4 of insulating material, for example fiberglass, is opened. inlets. The shape of the housing of the box-shaped aperture 4 is prismatic with the rounded edges of adjacent walls, but may be up to knee-shaped. The orifice plate 4 is composed of two adjacent parts detachably connected in a vertical plane, through which one of the outer jumpers 9 of the supply leads passes at the same time.

Before starting the electric motor is a ventilation housing occurs as follows: After opening the ventilation holes not shown in the upper part of the housing £ 0 ^e blown air inlets aeration pipe 2 to the front space of the electric motor. The bulk of the air passes through the through hole of the first side partition 6 into the box-shaped diaphragm 4, which directs it to the bottom of the power supply housing 3. The reflected air passes around the heaters 2 »of the ends of the power cables 11, the busses 12 and the power supply jumpers 9 upwards through the vertical channel and, after venting the other areas of the machine, leaves through the ventilation openings out of the housing.

256 498 of the body 5 are only operated as needed, for example when ventilating after a long standstill of an electric motor located in an unheated engine room, especially in winter, when the insulation of its electrical conducting parts may become wet. By heating the flowing air it is ensured that it is dried, whereby its insulating strength is again restored.

The design with the placement of the box-shaped orifice plate 4 is also used in the operating mode of the electric motor to direct the gaseous refrigerant into the underfloor spaces, i.e. the power supply box 3, thereby ensuring cooling of the power cable ends 11 and the power supply jumpers 9.

Claims (3)

1. A ventilating device of a high-performance electric motor in a above-ground cabinet, provided with at least one front side of a prismatic power supply cabinet which is spatially connected to the electric cabinet front space, part of which is a separating partition in front of the winding fronts; a vertical channel is formed by adjacent side bulkheads in which they pass from the power supply housing to the stator windings of the power supply jumper passages, wherein the inlet opening of the venting duct extends from the side of the electric housing to the lower part of its front space, 2) the venting pipe has a lower part of the opposite first side wall (6) provided with a through hole, to the edges of which there is an open front side of the boxes from inside the vertical channel (13) an insulating material, the open bottom side of which is terminated in the power supply housing (3). Ventilation device according to Claim 1, characterized in that the box-shaped screen (4) consists of two parts which are detachably connected in a vertical plane parallel to the front wall of the electric motor housing (1). Ventilation device according to claim 1, characterized in that heating elements (5) are located in the power supply housing (3).