DE8136680U1 - ELECTROMAGNETIC FANFARE - Google Patents

Description

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Ik. 12. 1981 Ws / Hm

ROBERT BOSCH GMBH, 7000 STUTTGART 1

Electromagnetic Fanfare j

State of the art I

$ The invention is based on an electromagnetic §

Fanfare according to the genre of the main claim. With a · <

such, well-known fanfare (DE-AS 12 kO 7β2) is |

the sound strength by a "certain dimension of the J

Horn aimed +, where the length of the straight |

linear section at the membrane-side end of the sound |

funnel is equal to the quotient of the wavelength of the |

Fundamental and a coefficient of about ^ ₃ U. At |

the well-known fanfares, however, is the horn in f

With regard to the sound pressure level in the frequency band between '?

e see 1,8OO and 3-550 Hz through the shape of the sonic J

funnel not optimal. t

The present solution, on the other hand, aims at %

to dimension the bell jar so that upon delivery

of an acoustic signal, the fanfare is at its highest \

Sound pressure level in the frequency range between I.8OO and Has 3.55O Hertz.

Advantages of the invention

The fanfare according to the invention with the characteristic Features of the main claim has the advantage over the known designs that by raising of the sound pressure level by several dB in the audible range, the volume of the fanfare has been significantly improved. Another advantage is that the proposed dimensions of the horn make it possible to this helically bent within the outer diameter to accommodate the housing closed by the membrane .

The measures listed in the subclaims are advantageous developments and improvements the features specified in the main claim are possible.

drawing

An embodiment of the invention is shown in the drawing shown and explained in more detail in the following description. Figure 1 shows an electromagnetic Fanfare in the side view, FIG. 2 a cross section through the bell of the fanfare according to FIG 1 and FIG. 3 shows the elongated horn according to FIG. 2 with its cylindrical, conical and exponential extended section.

Description of the embodiment

In Figure 1, the electromagnetic fanfare is 10 designated. Your cup-shaped, set off in steps

• I · «•• 1111 1

τ 3 -

On its open end face, the housing 11 has a membrane 12, the outer area of which is flanged around the outwardly curved edge 11a of the housing 11. The membrane 12 carries a plunger armature 13 in its center, which is part of a vibration drive arranged in the housing 11. The drive consists of an interrupter (not shown), an excitation winding 1 k and an iron core 15. The other end of the field winding is 1 h

It's about the breaker contact with a second, no

() visible plug connection in the housing 11 contacted. The fanfare is fastened in the motor vehicle * with a fastening strap 17, which is on a through the housing 11 protruding threaded bolt 18 of the Iron core 15 is fastened by means of a nut 19. The membrane 12 is made on its front side by a thermoplastic existing, essentially flat plate 20 covered. The space between the plate

20 and the membrane 12 forms a compression chamber 21, from which the sound waves generated by the membrane 12 be emitted through a central opening 22. In front of the plate 20 there is a plastic shaped, helical horn 23, through which the from the opening 22 of the compression chamber

21 escaping sound waves get into the open air.

Figure 2 shows a cross section through the horn 23. The course of the horn 23 is like this chosen that the radius of curvature E of the bell's central axis X is nowhere smaller than the width of the bell B is in the front, cylindrical funnel portion 23a.

In Figure 3, the inner contour of the horn from Figure 2 is shown in a stretched design. File is It can be seen that the horn 23 has a first cylindrical starting from the opening 22 of the compression chamber 21 Section 23a, a steplessly adjoining, conically widening second section 23b and has an exponentially expanding third section 23c adjoining this steplessly, for optimization the volume when emitting an acoustic signal should be the sound pressure level in the easily audible frequency range achieve optimal values between 1,800 and 3,550 Hz.

For this purpose, the length L1 of the first section 23a of the horn 22 corresponds with a deviation of -10 % of its cross-sectional area A1, which is shown hatched in FIG. In the exemplary embodiment

2 according to FIG. 1, the cross-sectional area A1 is 75 mm

and the length L1 is consequently 75 mm. The following therefore applies: L1 = A1 _ + 10 %

The length L2 of the second section 23b of the horn is 1 ₅ 6 times the length L1 of the first section 23a -10 %. For the horn 23 from FIG. 2, this results in a length L2 of 120 mm. The following applies:

L2 = 1.6 L1 + 10 %

In addition, on this length L2, the central conical section 23b of the horn 23 expands to a cross-sectional area A2 at the end of this section to 5 times the cross-sectional area A1 of the first section 23a - 10 %. For the bell jar 23 according to FIG

2 results from this at the end of the second section 23b cross-sectional area
A2 = 5 A1 + 10 %

a cross-sectional area A2 of 380 mm. The following applies:

The cross-sectional area Ax for the third section 23c of the horn 23 is calculated according to the function:

Ax = Al. e ^mX ;

Al is the cross-sectional area of the first section 23a, m is a constant of 0.03U - 10 $ and χ is the distance of the cross-sectional area Ax from the starting point 0 of the exponential function at χ = 0. Since the third section 23c of the horn 23 is conical extended section 23b connects steplessly, the starting point 0 of the exponential function lies in the conical section 23b. Therefore, this is not realized part of the exponentially expanding the third portion 23c of the horn 23 shown in dashed lines - in Figure 3.

It follows that the third section 23c of the bell only begins where its cross-sectional

2 area Ax equal to the cross-sectional area A2 of 380 mm at the end of section 23b is (Ax = A2). The length

L3 of this third section 23c is therefore

0.375 times the length L1 of the first section 23a

- 10 %. This results for the exemplary embodiment

for the third section 23c a length L3 of 50 mm. The following applies:
(L3 = 0.66 A1 ± 10 %.

In order to achieve an optimal function of the horn 23 and the greatest possible Klanpj purity, are the transitions between the individual sections 23a, 23b and 23c of the horn 23 in the execution rounded off with a large radius according to FIG. These roundings and the largest possible bending radii of the helical horn 23 are intended to prevent turbulence of the sound waves in the horn 23. This has been achieved in an advantageous manner in the design of the horn 23 according to FIG.

1U. 12.19βΐ Ws / Hm

ROBERT BOSCH GMBH, 7OOO STUTTGART 1

Electromagnetic fanfare
summary

An electromagnetic fanfare is proposed that operates in the frequency range between 1,800 and 3,550 Hz should generate the greatest possible sound pressure level. For this purpose, the horn (23) is in one cylindrical, a conical and an exponentially extending section (23a-c) divided, their lengths and cross-sectional areas in a fixed relationship stand, whereby the cross-sectional area (A1) at the beginning of the horn (23) is to be assumed. The fanfare (10) can be used both for vehicles and for monitoring systems where In certain situations an acoustic signal is required (Figure 2),

Claims (5)

. 1981 Ws / Hm ROBERT BOSCH GMBH, TOOO STUTTGART 1 claims 1. Electromagnetic fanfare with a. -. "". the compression () chamber attached to the housing wall and an adjoining horn with a first, cylindrical section extending from the compression chamber, a steplessly adjoining, conically widening second section and with a continuously adjoining, exponentially widening third section, characterized in that a) the length (L1) of the first section (23a) with a deviation of -10 % of its cross-sectional area (A1) corresponds to that b) the length (L2) of the second section (23b) 1.6 times - 10 % of the length (L1) of the first section (23a) and that c) the cross-sectional area (Ax) for the third section (23c) according to the function A1. e, where A1 is the cross-sectional area of the first section (23), πι a constant from 0.03 ^ - 10 ^ and χ the distance of the cross-sectional area (AxJfrom the starting point (θ) of the Exponential function fx = 0). • ... U 2. Electromagnetic fanfare according to claim 1, characterized in that in the conical second section (23 "b) of the horn (23) the cross-sectional area (S2) at the end of the section (23b) is 5 times - 10 % of the cross-sectional area (A1) of the first section (23a). 3. Electromagnetic fanfare according to claim 2, characterized in that the third section (23c) of the horn (2o) only begins with a cross-sectional area which is equal to the cross-sectional area (A2) at the end of the conical second section (23b) and that its length (L3) is 0.66 times -10 % of the length (L1) of the first section (23a). H. Electromagnetic fanfare according to one of the preceding claims, characterized in that the transitions between the individual sections (23a, 23b, 23c) of the horn (23) are rounded. 5. Electromagnetic fanfare according to one of the preceding claims, characterized in that the Horn (23) is arranged in a helical shape in front of the membrane (12) and that the radius of curvature (R) of the central axis (X) of the bell (23) is nowhere smaller than the width of the bell (B) in its first, cylindrical section (23a)