SU1723410A1 - Reflector of lighting fitting for greenhouse - Google Patents

Abstract

Use: in greenhouses to reflect light. The invention: the reflector contains an elastic cylindrical arch, the ends of a cylindrical arch, longitudinal cylindrical flanges of the arch and its ends, embedded rods. The spatial elastic construction is formed as follows. The cylindrical arch has a longitudinal symmetrical fold and two symmetrical triangular cuts. The ends of the cylindrical arch are made in the form of inclined elastic arches from a horseshoe-shaped sheet with a symmetric bend and a radial arrangement of this bend and cylindrical flanging of the ends. The inclined ends in the upper part form internal dihedral protrusions, which are included with an emphasis in the triangular notches of the elastic cylindrical arch. The arches are connected by spring-loaded inserts, which are included in the cylindrical flanging of the arches. 2 hp f-ly, 9 ill. with C

Description

This invention relates to lighting engineering, in particular, to the design of reflectors for luminaires of thin-sheet material.

The aim of the invention is to improve the performance of the reflector.

Figure 1 shows the reflector, bottom view; figure 2 is the same, side view; on FIG. 3 - the same, end view; 4 shows the initial blank of the cylindrical arch of the reflector; 5 shows the final blank of the cylindrical arch of the reflector; 6 shows the initial blank of the inclined arch of the reflector; 7 - the final blank of the inclined arch of the reflector; on Fig - the inclined arch of the reflector, EI below; figure 9 - the same, inside view.

The reflector contains a cylindrical arch 1 with side sheets (sides) 2, flanging 3, fold 4 and with notches 5; an inclined arch 6 with side sheets (sides) 7, flanging 8, folds 9, wedges 10 and mortgage bars 11; strapping 12.

The reflector is formed by a three-arch construction of thin elastic sheets with a collapsible base and a roof. At the base, the reflector is formed by placing the arches 6 with the ends of their embedded bars 11 into the holes of the ends of the flanging 3 of the cylindrical arch 1 blank. The blank elastically bends to form the arch 1 with parallel flanging 3 and the fold 4. The profile of the arch 2 is calculated by the method of obtaining lines

1 th co

four

deflection of elastic shells with stepwise variable stiffness based on a preliminary lighting calculation of the flow balance. The base of the reflector design is a collapsible hexagonal frame of flanging 3 and 8 and fixed rods 11. The joining of the arches 1 and 6 is carried out by inserting a wedge 10 of the arches 6 from the inside into triangular notches

5 with a spring loaded press 1 along its ends to its base plane and thrust from this plane due to the elastic deflection of the sheets (sides) 7 while redistributing their surplus formed by symmetrical bending of the bars 11 and the beam-like arrangement in the arches 6 of their flanges 8 and folds 9. Adjacent to the fold lines 4 and 9 of the reflector, its longitudinal sections form a clamped internal dihedral protrusion with symmetrically concave edges reflecting radiation beams in the lamp, bypassing the lamp both in its longitudinal and in the top. general parts Heating such a reflector in a lamp with a powerful gas discharge lamp causes thermal linear elongation of sides 2 and 7 of arches 1 and 6 along their elastic thrust between the pinching of the sheet of arches 1 and b, i.e. between the outer supports of their edges (made in the form of bar-reinforced 11 flanging 3 and 8) and intermediate supports (in the form of folds 4 and 9). At the same time, simultaneously increasing the arrows of deflection of sides 2 and 7 (due to a certain rigidity of the arrangement of the folds 4 and 9 relative to the base of the reflector, obtained by capturing the arch 1 by the arches 6 over the arch), the simultaneous movement of the folds 4 and 9 relative to the base of the reflector in the plane of its symmetry occurs. With this arrangement of the folds 4 and 9, the convexity of the edges of the cutouts 5 and the concavity of the faces of the wedges 10 are formed, which provides a more rigid stop of the wedges 10 to the tops of the cutouts b and creates a point contact of the arches 1 and 6 along the arch of the reflector, which does not interfere during heating or cooling the lamp to increase or decrease the lighting cavity of the reflector, i.e. inhale and exhale forming her breath. Preservation of the gripping of the arches 6 of the arch 1 while breathing the reflector is provided by the wave-shaped elastic deflection of the sides 7 - the arch external to the arch

6 and internal at its base. In this case, the edges of the wedges 10 resiliently abut against the side tops of the notches 5 from inside the reflector, and their bends 9 are against the central tops of the notches 5 from the outside of the reflector. Try to straighten out, the internal folds of the sides of the 7 arches

6 create resistance to the output of the wedges 10 from the notches 5 in the direction of the base of the reflector, and their external folds - resistance to the exit of the wedges 10 from the notches 5 in

the direction of the end of the arch 1.

The absence of an optimal (oval) shape of the reflector is compensated by a more uniform distribution of the radiation of the luminaire through the use of

0 of the reflecting surface of the arches 1 and 6 of the microrelief with alternating linear protrusions with a lateral cut located along folds 4 and 9. At the same time, a circular change in the reflective properties of its surface is created near the axis of the reflector, having a maximum reflection in its longitudinal plane and smaller in the transverse one. This is created by the difference in the course of the rays reflected by the protrusions of the microrelief, until they exit the recess between the projections, i.e. along the recess or across.

The straps 12 are designed to simplify the assembly and disassembly of the reflector.

5 Improving the performance of the reflector is achieved by reducing the distortion of the reflector by breathing the reflector when it is heated, reducing its size and material consumption by making the ends of the cylindrical arches of a horseshoe-shaped sheet with a fold 9 (which reduces the longitudinal size of the reflector while maintaining the efficiency of radiation output.

5 When 4 arches 1 are folded at an angle A, the reflecting surface of the sheets (sides) 2 is filled with a reflection of the unfolded surface of the discharge tube (burner) of the lamp, which has the greatest brightness

0 of the central part of the reflector, at angles to the longitudinal plane of the reflector within 40 - 60 °. The bend of the arches 6 at an angle B in the longitudinal plane of the reflector (Fig. 8) and the location of the base of the arches 6 at an angle

5 creates a latitudinal filling of the reflecting surface of the arches 6 at the place of the folds 9 by reflecting the unfolded surface of the lamp burner having the greatest brightness at angles of 40-60 ° to the longitudinal plane of the reflector and its axis. The blanks of the arches 6 are molded from sheets (fig.b), made their linear edges with cylindrical flanging 8 when rolling in their linear edges of the bars 11, bent in the marginal areas

5 at an angle B (FIG. 7). The molding of the arches 6 is carried out by flexible blanks (Fig. 7), rods 11 in the middle at an angle T, and a sheet - at an angle B (Fig. 8).

A feature of the arrangement of arches 6 in the arch 1 is the reduction of the seats of the arches 6 in it, which is ensured by making in the arch 1 of the central apex a cutout 5 at a distance from the plane passing perpendicular to the reflector light opening through the arbor 3 of the smaller flanges 3 1.5-2 times the distance from the top of the wedge 10 arch b in arch 1 not fixed in notch 5. Further connection of arches 1 and 6 along the arch of the reflector is carried out by moving arch 6 to the final operating position, shifting the wedge 10 to the notch 5 with an increase in external p parties encircling portions 7 in the roof reflector and the formation of the internal deflection portions at the base sides of the reflector. The wedge 10 is inserted into the cutout 5 until the elastic stop from the inside by the reflector side edges into the side peaks of the cutout 5 and part of the side edges of the arch 6 into the sheet of the arch 1, and from the outside the reflector of the bend 9 into the fold 4. Moreover, the deflections of the sides 7 are created between the arches 6 and the arch 1 slotted holes with the formation of additional space in the middle part of the arch 1 by the side edges of the middle part of the arches 6 (FIG. 3), which improves the rigidity of the grip by the wedges 10 notches 5 of the arch and makes the three-arch design of the reflector in the breathing mode more dynamic. The radiation fluxes coming through these slots are reflected by the continuation of the tape arch 1 for the sheet of arch 6. The detachable connection of the arches b and 1 is provided with removable straps 12 (Fig. 1) of rods with springs fitted with hooks at the ends, which allows for the assembly and disassembly of the reflector without a tool. The unfolding of the arch 1 into the workpiece (Fig. 5) and the nature of the shape of the arches 6 outside the reflector allow the parts of the reflector to be packaged

0

five

0

five

0

five

during transportation and storage. On the hubs 12, a stop is placed for movement in order to maintain the lamp in a horizontal position.

Claims (3)

1. Reflector lamp for greenhouses, containing an elastic cylindrical arch, the ends of a cylindrical arch, longitudinal cylindrical flanges of the arch and its ends, embedded elements in the form of elastic rods connecting the elastic cylindrical arch and its ends, and forming a spatial elastic structure of the tension, similar to the fact that, in order to improve performance, the elastic cylindrical arch is made with a longitudinal symmetrical bend, oriented inside the reflector, and two symmetrical triangular The cuts in the upper part of the elastic cylindrical arch, and the ends of the cylindrical arch are made in the form of inclined elastic arches with a symmetric fold, oriented inside the reflector in such a way that a beam-like arrangement of this fold and cylindrical flanges of the ends is formed, while formed in the upper parts of the ends of the cylindrical arch: the dihedral protrusions are located in the triangular notches of the cylindrical arch and abut the vertices of the said triangular notches. 2. Reflector pop.1, characterized in that the inner surface of the arches is made with micro-relief in the form of alternating linear protrusions located along the folds of the arches. 3. Reflector pop.1, characterized by the fact that the ends of the cylindrical arch are connected by stitches. .40 1.1 four 2 T i thirty FIG. 6 Editor A, Makovska Phage.9 Compiled by E. Alekseev Tehred M.MorgentalKorrektor M. Sharoshi