DE19930006B4 - A method of manufacturing a solenoid valve and a solenoid valve made by this method - Google Patents

Abstract

An electromagnet (48) with a coil (10, 10a, 10b) and a method for producing an electromagnet (48) are proposed. At least two turns (26) of at least one winding layer (28) of the coil (10, 10a, 10b) are short-circuited. This enables a simple adjustment of the pressure-current characteristic of a solenoid valve (46). In the manufacturing process, the electromagnet (48) is measured after manufacturing. Depending on the measurement, at least two turns (26) of the coil (10, 10a, 10b) are short-circuited in such a way that a region (58) predetermined for the electromagnet (48) is reached.

Description

The invention is based on one Method of manufacturing an electromagnet of the type of the independent Claim. A solenoid valve manufactured in this way has one therein mounted electromagnet, the at least one coil and has soft magnetic components, and a hydraulic part. This is particularly the case with solenoid valves such as proportional valves Pressure-current characteristic is an essential quality feature. The slope of the Characteristic curve is influenced from the hydraulic part and from the solenoid of the solenoid valve. By batch-related Fluctuations lead to changes in the slope of the pressure-current characteristic, which leads in part to committee. A known method of change the slope is, for example, a mechanical adjustment by changing the Air gap.

From the DE 38 22 627 C2 is a choke coil for broadband application such as for use as a broadband choke, as a partial winding of a transformer, as a crossover and the like. In this choke coil, individual turns are capacitively and / or inductively, but essentially capacitively bridged.

From the DE 35 39 135 A1 the result is an adjustable air coil with a bobbin, on which a driver is movably mounted, which pulls the winding apart or compresses it for the purpose of inductance compensation.

By this measure, the disadvantages of from MEINKE / GUNDLACH, paperback of HF technology, third improved Edition, Springer Verlag, 1968, pages 26 to 34, known air coils be resolved. These air coils that are used in variometers and where an inductance adjustment by short-circuiting individual turns are not suitable for series production. By short circuiting not needed Coils will spray avoided.

Object of the present invention is a method of making a solenoid valve and a Create a megnet valve with which easy adjustment is possible. Solved this object with the features of claims 1 and 7.

The manufacturing method according to the invention of the electromagnet with the characterizing features of the independent claim the advantage that a simple adjustment possible is that a certain number of turns of the coil but at least two turns at least one winding layer are short-circuited.

It is particularly advantageous here Turns of the extreme Winding position in the area of the outer surfaces or limit washers by fusing, for example, soldering or laser welding or with a bridge short-circuit.

Process reliability is increased by between the two outermost Winding layers a component is inserted. Is this component electrical? conductive, can be a bridge omitted and it must not all turns are fused together. Know that Component has an electrical connection that protrudes from the coil body, can be easily attached to a connecting line.

It is particularly advantageous to have one to use such manufactured solenoid valve in a pressure regulator. This makes it easy to adjust the pressure-flow characteristic of the Solenoid valve possible.

For it is particularly cheap to manufacture manufacture the electromagnet and then measure the required Short-circuit the number of turns of the coil. After assembling the electromagnet and the hydraulic part to a solenoid valve becomes the pressure-current characteristic on a test bench added. This will additionally the tolerances of the hydraulic part detected. The measured actual pressure-current characteristic deviates from a predetermined range, then a comparison can also be carried out short of turns.

Other advantages and beneficial Developments of the switching device according to the invention result itself from the subclaims and the description.

An embodiment of the invention is shown in the drawing and in the description below explained in more detail. It demonstrate

1 a coil of an electromagnet in a longitudinal section,

2 a modified coil in longitudinal section,

3 another modified coil in longitudinal section,

4 the bobbin after the coil 3 with a housing in a perspective exploded view,

5 a solenoid valve in a longitudinal section and

6 a diagram with pressure-current characteristics.

In the 1 is a coil 10 shown, which is provided for electromagnets, in particular of solenoid valves. The sink 10 has a bobbin 12 with a hollow coil core 14 on, on the end faces 16 . 18 one limiting disk each 20 . 22 is trained. On the bobbin 12 is a winding 24 wound.

As from the 1 emerges are at least at least two turns 26 at least one winding layer 28 shorted. In the present exemplary embodiment, there are five turns 26 , where there are also more or fewer turns 26 could be. It is advantageous for manufacturing reasons, the outermost winding layer 28 fully wound, as this causes the winding to float 24 is prevented during injection molding.

At the in the 1 illustrated coil 10 are - as already mentioned - at least two turns 26 the top winding layer 28 short-circuited, which is advantageous for manufacturing reasons. The at least two turns 26 are thus short-circuited. This will apply to the winding 24 the coil 10 realized by the turns 26 are fused together. This can be easily implemented by soldering or laser welding.

As from the 2 shows, are with the modified coil 10a the turns 26 over a bridge 30 short-circuited at the first and the last of the short-circuited turns 26 is attached.

It should be noted that the remaining parts shown have the same reference numerals as the parts of the 1 and that they have the same structure and the same function.

With the modified coil 10b to 3 is at least over part of the circumference between the two outermost winding layers 28 . 32 an essentially flat component 34 arranged, which is at least partially over the length of the coil 10b and thus also at least partially over the axial length of the winding layers 28 . 32 extends. This ensures higher process reliability in production, since short-circuiting in the area of the component 34 is carried out. This provides insulation to lower winding layers 32 so that they cannot be damaged when short-circuited.

The component is advantageous 34 electrically conductive. This means that only the first and the last of the turns to be short-circuited 26 with the component 34 get connected. It is useful if the component 34 out of the bobbin 12 protrudes and has an electrical connection. This simplifies the electrical connections for the coil 10b ,

It should be noted that the remaining parts shown have the same reference numerals as the parts of the 1 and that they have the same structure and the same function.

From the exploded view of the 4 shows that the coil 10 . 10a . 10b in an advantageously sleeve-shaped or pot-shaped housing 36 is arranged, preferably in an axial slot 38 is trained. This results in advantages in manufacturing, which will be discussed later.

From the 4 can also be seen that the component 34 is slightly arched so that it is attached to the windings 28 . 32 snugly. It has a first section in the axial direction 40 on that of the length of the bobbin 12 equivalent. In the boundary washers 20 . 22 there is a recess on the circumference 42 to hold the component 34 educated. The first section 40 of the component 34 closes a second, preferably narrower section 44 on. This causes the component to protrude 34 out of the bobbin 12 out and points to the second section 44 an electrical connection to which, for example, a wire can be soldered.

In the 5 is a coil 10 in a solenoid valve 46 , assembled or used shown. With the solenoid valve 46 it is advantageously a proportional valve, in particular a pressure regulator. The solenoid valve 46 However, it can also be designed as a 3/2-way valve, a pulse width modulated solenoid valve or a switching valve. The sink 10 is part of the electromagnet 48 of the solenoid valve 46 , The electromagnet 48 can also have more than one coil 10 exhibit. The sink 10 is in one case 36a of the electromagnet 48 or the solenoid valve 46 assembled. The housing 36a or the solenoid valve 46 has a slot 38a which serves the short-circuiting process. The electromagnet 48 points out of the coil 10 and the housing 36a still soft magnetic components; these are essentially a pole core in particular 49 and / or an anchor 50 , However, other soft magnetic components can also be present. The solenoid valve 46 also has a hydraulic part 51 ,

In the 6 is a diagram with three different pressure-current characteristics 52 . 54 . 56 shown that have different steep slopes. A pressure-current characteristic 52 . 54 . 56 gives the course of the pressure p at a proportional valve 46 over the current I at. The greater the current I, the greater the pressure p. At the beginning and at the end of the pressure-current curve 52 . 54 . 56 they have a flatter course than in the middle part, the work area.

A method of manufacturing the electromagnet 48 does the following:
First, the bobbin 12 the coil 10 . 10a . 10b with the winding 24 wrapped and in the case 36 built-in. Then the pole core is assembled 49 and the anchor 50 , causing the electromagnet 48 arises. Then the actual values of the electromagnet 48 measured. The actual values deviate from for the electromagnet 48 predetermined target values, at least two turns are made depending on the actual values 26 so short-circuited that for the electromagnet 48 predetermined target values can be achieved.

The short-circuited turns 26 are soldered or welded together. Alternatively, the turns 26 with a bridge 30 shorted. For this purpose, a processing station can be integrated into the test bench on which the measurement is carried out, or it can be connected downstream of this station, where the short-circuiting is then carried out. The process of short-circuiting is advantageously through the axial slot 38 . 38a in the housing 36 or in the solenoid valve 46 performed in which the coil 10 . 10a . 10b was arranged before measuring.

This process, which can also be referred to as adjustment, can thus be carried out in a simple manner on the finished electromagnet 48 carry out.

After short-circuiting the affected turns 26 , whose insulation has been stripped by the short circuit, advantageously isolated again, which causes the winding 24 is protected. It is also appropriate to use the slot 38 . 38a after the short circuiting process.

The electromagnet 48 is already in the solenoid valve before measuring 46 assembled. As a result, the proportions of the hydraulic part also flow into the measurement or measurements 51 on. The test values of the actual pressure-current characteristic curve are then, for example, on a test bench 52 added for clarification outside the between the target pressure-current characteristic curves 54 and 56 lying, predetermined range 58 runs. solenoid valves 46 that have actual pressure-current characteristics in this area 58 are okay. With electromagnets 48 of solenoid valves 46 whose actual pressure-current characteristics are outside the specified range 58 must be at least two turns 26 at least one winding layer 28 so short-circuited that one for the solenoid valves 46 predetermined course that in the area 58 lies, is reached. The actual pressure-current characteristic curve 52 is too steep in the present exemplary embodiment. By correspondingly short-circuiting turns 26 becomes the actual pressure-current characteristic curve 52 flatter. So there must be so many turns 26 that shorted that area 58 is achieved.

So it is possible that the electromagnet 48 first of all undergoes a first adjustment and that after assembly in the solenoid valve 46 a fine adjustment takes place or that an adjustment takes place only after the electromagnet has been installed 48 with the hydraulic part 51 to the solenoid valve 46 he follows.

Claims (8)

Method of manufacturing a solenoid valve ( 46 ) into which an electromagnet ( 48 ) that has at least one coil ( 10 . 10a . 10b ) and has soft magnetic components, and a hydraulic part ( 51 ) is mounted, characterized in that after the manufacture of the solenoid valve ( 46 ) whose pressure-current characteristic ( 52 ) is measured and depending on the actual values at least two turns ( 26 ) the coil ( 10 . 10a . 10b ) are short-circuited so that for the solenoid valve ( 46 ) specified target values or a range ( 58 ) is reached. Method according to claim 1, characterized in that the connected turns ( 26 ) are soldered or welded together. Method according to claim 2, characterized in that the connected turns ( 26 ) with a bridge ( 30 ) are short-circuited. Method according to one of claims 1 to 3, characterized in that the coil ( 10b ) in a housing ( 36 . 36a ) is arranged, which has a slot ( 38 . 38a ) for the short-circuiting process. A method according to claim 4, characterized in that the slot ( 38 . 38a ) is closed after the short-circuiting process. Method according to one of claims 1 to 5, characterized in that the short-circuited turns ( 26 ) be isolated again. Magnetic valve ( 46 ) produced according to one of claims 1 to 6. Magnetic valve ( 36 ) according to claim 7, characterized in that the solenoid valve ( 48 ) is a pressure regulator, a 3/2-way valve, a pulse width modulated solenoid valve or a switching valve.