Electromagnetic valve device

An electromagnetic valve device includes a valve operating unit formed by disposing valve components in a valve housing having a guide cylinder and mounted to a base member, and a tip end of the guide cylinder and a housing body are magnetically connected to each other by a magnetic path defining frame surrounding a coil wound around a bobbin. The bobbin is buried in a mold section made of synthetic resin to form a coil unit. The coil unit is mounted to the base member. One end of the magnetic path defining frame is formed with a fitting bore through which the tip end of the guide cylinder is fitted, and the other end of the magnetic path defining frame is capable of abutting against the housing body. The magnetic path defining frame is mounted to a coil-correspondence portion of the mold section. The guide cylinder is loosely passed through a center bore of the bobbin. With this arrangement, a magnetic path can reliably be formed by the magnetic path defining frame, and the coil, bobbin and magnetic path defining frame can easily be mounted to each of the valve operating units.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an electromagnetic valve device comprising 
a plurality of valve operating units, each including valve components such 
as a stationary core, a movable core, a valve body and a return spring, 
which are disposed in a valve housing having a guide cylinder connected at 
its base end to a housing body fitted to and secured to a base member; a 
plurality of bobbins each having a center bore through which each of the 
guide cylinders are passed; a plurality of coils each wound around each of 
the bobbins; a plurality of magnetic path defining frames each of which 
surrounds each of the coils to magnetically couple a tip end of the guide 
cylinder and the housing body to each other. 
2. Description of the Related Art 
The above described electromagnetic valve device is already known from 
Japanese Patent Application Laid-open No. 7-47938, for example. 
In such a known electromagnetic valve device, the plurality of bobbins 
around which the coils are wound and the plurality of the magnetic path 
defining frames are assembled as a unit so as to be common to a plurality 
of valve operating units mounted to a base member. And in a state where 
each of the valve operating units is mounted to the base member, the 
common unit is mounted to the base member to simplify the assembling 
operation. However, there is a tolerance in relative position between the 
plurality of valve operating units mounted to the base member and each of 
the bobbins and magnetic path defining frames in the common unit. 
Therefore, in the electromagnetic valve device in which each of the 
magnetic path defining frames is positioned at a constant location with 
respect to each of the bobbins, as in the above described publication, it 
may be difficult, in some cases, to smoothly insert the guide cylinder of 
the valve operating unit into each of the bobbins due to the tolerance in 
relative position. Further, if an inner diameter of the center bore of the 
bobbins is set greater than an outer diameter of the guide cylinder so as 
to absorb the tolerance in relative position, a relatively large gap is 
produced between the magnetic defining frame and the guide cylinder and 
thus, it may be difficult, in some cases, to form a magnetic path by the 
magnetic path defining frame. 
SUMMARY OF THE INVENTION 
The present invention has been accomplished in view of the above 
circumstances, and it is an object of the invention to provide a 
electromagnetic valve device in which the magnetic path can reliably be 
formed by the magnetic path defining frame, and each of the bobbins around 
which the coil is wound and the magnetic path defining frame can easily be 
assembled to each of the valve operating units. 
To achieve the above object, the present invention provides an 
electromagnetic valve device comprising: a plurality of valve operating 
units, each including valve components such as a stationary core, a 
movable core, a valve body and a return spring, which are disposed in a 
valve housing having a guide cylinder connected at base end thereof to a 
housing body fitted to and secured to a base member; a plurality of 
bobbins each having a center bore through which each of the guide cylinder 
is passed; a plurality of coils each wound around each of the bobbins; a 
plurality of magnetic path defining frames each of which surrounds each of 
the coils to magnetically couples a tip end of the guide cylinder and the 
housing body to each other; wherein the plurality of bobbins having the 
coils wound therearound are buried in a mold section made of a synthetic 
resin to form a coil unit, the coil unit being mounted to the base member, 
and each of the magnetic path defining frames being movably mounted in a 
cylindrical coil correspondence portion formed in the mold section to 
cover each of the bobbins and each of the coils wound around the bobbins; 
and the magnetic path defining frames each provided at one end thereof 
with a fitting bore into which the tip end of the guide cylinder is 
fitted, the other end of each of the magnetic path defining frames being 
capable of abutting against the housing body, the magnetic path defining 
frames being movably mounted to the coil-correspondence portions, each of 
the guide cylinders being loosely passed through the center bore of each 
of the bobbins. 
With the above arrangement, the tolerance in relative position between the 
plurality of valve operating units mounted to the base member and each of 
the coil-correspondence portions in the coil unit mounted to the base 
member is absorbed by a loose movement of the magnetic path defining 
frame, thereby allowing the guide cylinder to smoothly pass through the 
center bore of each of the bobbins, and allowing the guide cylinder to 
easily fit into the fitting bore of the magnetic path defining frame. 
Therefore, the bobbins and the magnetic path defining frame can easily be 
mounted to the coil unit, and the magnetic path can reliably be formed by 
the magnetic path defining frame. 
According to another aspect of the invention, the electromagnetic valve 
device further includes springs each provided between each of the 
coil-correspondence portions and each of the magnetic path defining frames 
for biasing each of the magnetic path defining frames in a direction to 
come into abutment at its other end against each of the housing bodies. 
With this arrangement, the magnetic path defining frame can reliably be 
abutted against the housing body, and the magnetic path can reliably be 
formed by the magnetic path defining frame. 
The above and further objects, features and advantages of the present 
invention will become more apparent from the following detailed 
description taken in conjunction with the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
A first embodiment of the present invention will now be described with 
reference to FIGS. 1 to 11. First, in FIGS. 1 and 2, there is shown an 
electromagnetic valve device for an antilock brake control of a vehicle, 
such as a four wheel vehicle, for example. The electromagnetic valve 
device includes four normally closed type electromagnetic valves V.sub.o, 
and four normally opened type electromagnetic valves V.sub.c, each 
independently corresponding to each of wheel brakes, and each disposed on 
a common metal base member 11. 
Each of the normally opened electromagnetic valves V.sub.o comprises a 
valve operating unit 12.sub.o, a coil unit 13 which is common to each of 
the normally opened electromagnetic valves V.sub.o and each of the 
normally closed type electromagnetic valves V.sub.c, and electromagnetic 
path defining frame 14 mounted to the coil unit 13. 
The valve operating unit 12.sub.o includes a valve housing 17.sub.o which 
comprises a guide cylinder 15.sub.o formed into a bottomed cylindrical 
shape whose leading end is closed, and a housing body 16.sub.o to which a 
base end of the guide cylinder 15.sub.o is continuously formed. Disposed 
in the valve housing 17.sub.o are valve components such as: a stationary 
core 18.sub.o fixedly disposed within the base end of the guide cylinder 
15.sub.o ; a movable core 19.sub.o accommodated in the guide cylinder 
15.sub.o such as to oppose to the stationary core 18.sub.o ; a valve body 
21.sub.o which is capable of sitting on a valve seat member 20.sub.o 
fixedly mounted to the valve housing 17.sub.o and which is operatively 
connected to the movable core 19.sub.o ; and a return spring 22.sub.o for 
biasing the movable core 19.sub.o in a direction to separate away from the 
stationary core 18.sub.o, i.e., for biasing the valve body 21.sub.o in a 
direction to separate away from the valve seat member 20.sub.o. 
The housing body 16.sub.o is formed into a stepped cylindrical shape and is 
made of magnetic metal. One end of the housing body 16.sub.o is integrally 
and coaxially formed with the stationary core 18.sub.o which is formed 
cylindrically. The guide cylinder 15.sub.o is made of non-magnetic 
material such as stainless steel, and is formed into a thin bottomed 
cylindrical shape whose tip end is hemispherical and closed. The 
stationary core 18.sub.o is fitted into the base end of the guide cylinder 
15.sub.o, and such a base end is coupled to the housing body 16.sub.o by 
welding, for example. 
The base member 11 is formed at its one surface 11a with a stepped fitting 
bore 23.sub.o into which the housing body 16.sub.o can fit. Mounted to the 
base member 11 at its inner surface closer to an opening end of the 
fitting bore 23.sub.o is a retaining ring 24.sub.o which is engaged with 
the housing body 16.sub.o for preventing the latter from escaping out from 
the fitting bore 23.sub.o. Further, in a state where the housing body 
16.sub.o is fitted and fixed in the fitting bore 23.sub.o, the guide 
cylinder 15.sub.o is projected from the one surface 11a. Also, annular 
seal members 25.sub.o and 26.sub.o are mounted to an outer surface of the 
housing body 16.sub.o at locations spaced away from each other in its 
axial direction. An annular chamber 27.sub.o is formed between the seal 
members 25.sub.o and 26.sub.o, as well as between the base member 11 and 
the housing body 16.sub.o. 
The cylindrical valve seat member 20.sub.o is press-fitted and fixed in the 
housing body 16.sub.o. A valve stem 28 made of non-magnetic material is 
slidably fitted into the housing body 16.sub.o One end of the valve stem 
28 is abutted against one end of the movable core 19.sub.o which is 
slidably fitted in the guide cylinder 15.sub.o so as to oppose to the 
stationary core 18.sub.o, and a spherical valve body 21.sub.o which is 
capable of sitting on the valve seat member 20.sub.o is secured to the 
other end of the valve stem 28. Further, a valve chamber 29.sub.o is 
formed between the other end of the valve stem 28 and the valve seat 
member 20.sub.o, and the return spring 22.sub.o is accommodated in the 
valve chamber 29.sub.o for biasing the valve stem 28, i.e., valve body 
21.sub.o in a direction to separate away from the valve seat member 
20.sub.o. In a state where a magnetic attracting force toward the 
stationary core 18.sub.o is not applied to the movable core 19.sub.o, the 
movable core 19.sub.o is in a position retreated until received by the 
closed tip end of the guide cylinder 15.sub.o by a spring force of the 
return spring 22.sub.o. 
Mounted to the housing body 16.sub.o is a filter 31 interposed between the 
valve seat member 20.sub.o and a brake pressure passage 30 formed in the 
base member 11 and leading to a master cylinder which is not shown. A 
filter 32.sub.o is mounted to an outer periphery of the housing body 
16.sub.o at its portion facing the annular chamber 27.sub.o. The housing 
body 16.sub.o is provided with a passage 33.sub.o for bringing the valve 
chamber 29.sub.o into communication with the annular chamber 27.sub.o 
through the filter 32.sub.o. Further, disposed between the filter 31 and 
the valve seat member 20.sub.o of the housing body 16.sub.o is a check 
valve 34 which closes for returning a working liquid in the annular 
chamber 27.sub.o toward the brake pressure passage 30 when a pressure in 
the brake pressure passage 30 is lowered than that in the annular chamber 
27.sub.o. 
The normally closed type electromagnetic valve V.sub.c comprises a valve 
operating unit 12.sub.c, a coil unit 13 and a magnetic path defining frame 
14 mounted to the coil unit 13. 
The valve operating unit 12.sub.c including a valve housing 17.sub.c which 
comprise a guide cylinder 15.sub.c whose leading end is closed, and a 
valve housing continuously formed with a base end of the guide cylinder 
15.sub.c. Disposed in the valve housing 17.sub.c are valve components such 
as: a stationary core 18.sub.c fixedly mounted to a tip end of the guide 
cylinder 15.sub.c ; a movable core 19.sub.c accommodated in the guide 
cylinder 15.sub.c and the housing body 16.sub.c such as to oppose to the 
stationary core 18.sub.c ; a valve body 21.sub.c which is capable of 
sitting on a valve seat member 20.sub.c fixedly mounted to the valve 
housing 17.sub.c and which is secured to the movable core 19.sub.c ; and a 
return spring 22.sub.c for biasing the movable core 19.sub.c in a 
direction to separate away from the stationary core 18.sub.c, i.e., for 
biasing the valve body 21.sub.c in a direction to seat on the valve seat 
member 20.sub.c. 
The housing body 16.sub.c is formed into a stepped cylindrical shape and is 
made of magnetic metal. A cylindrical connection cylinder 35 is integrally 
and coaxially formed to one end of the housing body 16.sub.c. The guide 
cylinder 15.sub.c is formed into a thin cylindrical shape, and is 
comprised of a cylindrical sleeve 36 made of a non-magnetic material such 
as stainless steel. One end of the sleeve 36 is closed by fixing the 
stationary core 18.sub.c thereto, thereby forming the tip end of the guide 
cylinder 15.sub.c into a semispherical closed end. A base end of the guide 
cylinder 15.sub.c is fitted and coupled to the housing body 16.sub.c by 
welding, for example. 
The base member 11 is formed at its one surface 11a with a stepped fitting 
bore 23.sub.c into which the housing body 16.sub.c can fit. Mounted to the 
base member 11 at its inner surface closer to an opening end of the 
fitting bore 23.sub.c is a retaining ring 24.sub.c which is engaged with 
the housing body 16.sub.c for preventing the latter from escaping out from 
the fitting bore 23.sub.c. Further, in a state where the housing body 
16.sub.c is fitted and fixed in the fitting bore 23.sub.c, the guide 
cylinder 15.sub.c is projected from the one surface 11a. Also, annular 
seal members 25.sub.c and 26.sub.c are mounted to an outer surface of the 
housing body 16.sub.c at locations spaced away from each other in its 
axial direction. An annular chamber 27.sub.c is formed between the seal 
members 25.sub.c and 26.sub.c, as well as between the base member 11 and 
the housing body 16.sub.c. 
The cylindrical valve seat member 20.sub.c is press-fitted and fixed in the 
housing body 16.sub.c. The movable core 19.sub.c is opposed at its one end 
to the stationary core 18.sub.c, and is slidably fitted to the sleeve 36 
and the housing body 16.sub.c in the guide cylinder 15.sub.c. The 
spherical valve body 21.sub.c is capable of sitting on the valve seat 
member 20.sub.c, and is secured to the other end of the movable core 
19.sub.c. Accommodated between the one end of the movable core 19.sub.c 
and the stationary core 18.sub.c is a return spring 22.sub.c for biasing 
the movable core 19.sub.c, i.e., the valve body 21.sub.c in a direction to 
separate away from the stationary core 18.sub.c and to approach the valve 
seat member 20.sub.c. In a state where a magnetic attracting force toward 
the stationary core 18.sub.c is not applied to the movable core 19.sub.c, 
the valve body 21.sub.c is in a position to sit on the valve seat member 
20.sub.c. 
When the movable core 19.sub.c is magnetically attracted toward the 
stationary core 18.sub.c, if the movable core 19.sub.c is directed 
contacted with the stationary core 18.sub.c, a separating movement of the 
movable core 19c from the stationary core 18.sub.c is delayed due to 
residual magnetic force which is left when the magnetic attraction is 
stopped. In order to avoid such delay, a magnetic force killer 37 made of 
non-magnetic material is interposed between the stationary core 18.sub.c 
and the movable core 19.sub.c as shown in FIGS. 3 and 4. A valve chamber 
29c is provided between the stationary core 18.sub.c and the movable core 
19.sub.c, as well as between the movable core 19.sub.c and the valve seat 
member 20.sub.c. In order to avoid that a working liquid is shut in the 
valve chamber 29.sub.c and a smooth operation of the movable core 19.sub.c 
is obstructed, a single or a plurality of passage grooves 38 is provided 
in an outer surface of the movable core 19.sub.c between axially opposite 
ends thereof. 
The magnetic force killer 37 is formed into a ring-like shape out of a thin 
plate having a constant width D.sub.1 along a circumferential direction, 
for example. A depth D.sub.2 of each of the passage groove 38 is set 
larger than the width D.sub.1 of the magnetic force killer 37. With this 
arrangement, even if the magnetic force killer 37 is displace relative to 
the movable core 19.sub.c in the guide cylinder 15.sub.c on a plane 
perpendicular to the axis of the guide cylinder 15.sub.c, at least one of 
the passage grooves 38 is not closed by the magnetic force killer 37, 
therefore, portions of all of the passage grooves 38 are always opened at 
one end of the movable core 19.sub.c. 
Referring again to FIG. 1, a filter 32.sub.c is mounted to a portion of an 
outer periphery of the housing body 16.sub.c which faces an annular 
chamber 27.sub.c. The housing body 16.sub.c is provided with a passage 
33.sub.c for bringing the valve chamber 29.sub.c into communication with 
the annular chamber 27.sub.c through the filter 32.sub.c. The base member 
11 is provided with a brake pressure passage 39 which is connected to a 
wheel brake not shown and is in communication with the annular chambers 
27.sub.o and 27.sub.c which are to each other. The base member 11 is also 
provided with a release passage 40 which is connected to a reservoir not 
shown and is in communication with the valve seat member 20.sub.c of the 
normally closed type electromagnetic valve V.sub.c. 
The coil unit 13 is formed by burying a plurality of bobbins 41 having 
center bores 41a through which guide cylinders 15.sub.o and 15.sub.c of 
the valve operating units 12.sub.o and 12.sub.c, into a mold section 43 
made of synthetic resin, in a state where coils 42 are wound around the 
bobbins 41. The mold section 43 is clamped to the one surface 11a of the 
base member 11 and is integrally formed with a square frame 44 to which a 
lid 55 is detachably mounted. The mold section 43 includes a plurality of 
cylindrically formed coil-correspondence portion 43a for individually 
covering the bobbins 41 and the coils 42 wound around the bobbins 41. 
Referring also to FIG. 5, the magnetic path defining frame 14 is formed by 
coupling a rectangular magnetic path plate 49 and a bottomed cylindrical 
shaped magnetic path cylinder 52. The magnetic path plate 49 is opposed to 
one end of the coil-correspondence portion 43a and includes a fitting bore 
48 into which a tip end of any one of the guide cylinders 15.sub.o and 
15.sub.c projected from one end of the coil-correspondence portion 43a is 
fitted. The magnetic path cylinder 52 is provided at its central portion 
with an insertion bore 50 through which any one f the stationary core 
18.sub.o and the connection cylinder 35 is passed, and is closed by a 
dish-like to form a closed end. 
The bottomed cylindrical magnetic path cylinder 52 is integrally provided, 
at its portion at the side of its opened end, with a pair of connection 
arms 53, 53 and tip ends thereof abut against opposite ends of the 
magnetic path plate 49. Further, each of the connection arms 53, 53 is 
provided, at its opposite sides of its tip end, with a pair of caulking 
portions 53a, 53a. The caulking portions 53a, 53a are engaged by caulking 
with opposite ends of the magnetic path plate 49 which abuts against the 
tip ends of the connection arms 53, 53 thereby coupling the magnetic path 
plate 49 and the magnetic path cylinder 52 to each other to form the 
magnetic path defining frame 14. 
The magnetic path defining frame 14 is mounted to the coil unit 13 by 
coupling, the magnetic path cylinder 52 through which the 
coil-correspondence portion 43a is inserted and the magnetic path plate 
49, and the magnetic path plate 49 opposed to one end of the 
coil-correspondence portion 43a, to each other. A distance between the 
magnetic path plate 49 and the abutting portion 51, and an inner diameter 
of the magnetic path cylinder 52 are set so that the magnetic path 
defining frame 14 can loosely move with respect to the coil-correspondence 
portion 43a. The magnetic path frame 14 is mounted to the coil unit 13 
such that the magnetic path frame 14 can loosely move with respect to the 
coil-correspondence portion 43a. 
In such a magnetic path frame 14, a diameter of the fitting bore 48 formed 
in the magnetic path plate 49 is set such that when either one of the 
guide cylinders 15.sub.o and 15.sub.c is inserted into the fitting bore 
48, an inner surface of the fitting bore 48 is contacted with an outer 
surface of the one of the guide cylinders 15.sub.o and 15.sub.c. Whereas, 
a diameter of the insertion bore 50 formed in the abutting portion 51 is 
set such that the guide cylinder 15.sub.o or 15.sub.c can loosely be 
passed therethrough. 
A spring 54 is compressed between the other end of each of the 
coil-correspondence portions 43a and the abutting portion 51 of each of 
the magnetic path defining frames 14 for exhibiting a repulsion force in a 
direction for bringing the abutting portion 51 into abutment against 
either one of the housing bodies 16.sub.o and 16.sub.c. 
A conductor plate assembly 58 for electrically contacting with the coils 42 
of each of the normally opened type electromagnetic valves V.sub.o and 
each of the normally closed type electromagnetic valves V.sub.c is buried 
in the mold section 43 between an array of the normally opened type 
electromagnetic valves V.sub.o and an array the normally closed type 
electromagnetic valves V.sub.c. 
Referring to FIGS. 6, 7 and 8, the conductor plate assembly 58 comprises a 
common conductor plate 60 and two sets of a pair of individual conductor 
plates 61, 62, 63 and 64 which are integrally coupled with a conductor 
supporting base member 59 by insert-molding. 
As is shown in FIG. 9, before the coil unit 13 is formed, the bobbins 41 
around which the coils 42 are wound are arranged in two parallel arrays 
each consisting of four bobbins 41 to form two bobbin arrays R.sub.1 and 
R.sub.2. The conductor assembly 58 is disposed between the two bobbin 
arrays R.sub.1 and R.sub.2. Further, each of the bobbins 41 assumes an 
attitude such that opposite terminals 42a and 42b of the coil 42 wound 
around the bobbin 41 are disposed at the inner side of both the bobbin 
arrays R.sub.1 and R.sub.2. 
The conductor supporting base member 59 includes first and second sides 59a 
and 59b which are opposed to the bobbin arrays R.sub.1 and R.sub.2, 
respectively, and third and fourth sides 59c and 59d perpendicular to the 
first and second sides 59a and 59b, respectively, and is formed into a 
prism-like shape having a rectangular cross section made of synthetic 
resin. The individual conductor plates 61 to 64 are coupled by insertion 
with the first and second sides 59a and 59b, respectively, and the common 
conductor plate 60 is insert-coupled with the third side 59c among the 
third and fourth sides 59c and 59d. 
A connection terminal 60a connected to one of the terminals 42a of the coil 
42 wound around each of the bobbins 41 of both the bobbin arrays R.sub.1 
and R.sub.2 is provided by four each for each of the bobbin arrays R.sub.1 
and R.sub.2. The connection terminals 60a are projected sideways from the 
conductor supporting base member 59. The individual conductor plates 61 to 
64 are respectively provided with connection terminals 61a to 64a 
connected to other terminal 42b of the coil 42 wound around each of the 
bobbins 41. These connection terminals 61a to 64a are projected sideways 
from the conductor supporting base member 59 such as to form a pair with 
the connection terminals 60a of the common conductor plate 60. 
A coupler portion 59e is provided at longitudinally one end of the 
conductor supporting base member 59. Mounted to the coupler 59e are: a 
pair of connection terminals 60b, 60b mounted to the common conductor 
plate 60; and connection terminals 61b to 64b respectively mounted to the 
individual conductor plates 61 to 64. The conductor supporting base member 
59 is formed such that when the conductor plate assembly 58 is buried in 
and integrally formed with the mold section 43 together with the bobbins 
41, the coupler 59e is projected from the frame 44. By covering the 
coupler 59e with a covering member made of synthetic resin, another 
coupler 65 (see FIG. 2) to which the connection terminals 60b, 60b, 61b to 
64b is integrally formed with the frame 44. 
Meantime, when forming the individual conductor plates 61 to 64, a 
conductor plate material 66 is prepared by press molding as shown in FIG. 
10. The conductor plate material 66 comprises conductor plate portions 61' 
to 64' having shapes respectively corresponding to the individual 
conductor plates 61 to 64 which are respectively mounted to one of the 
first and second sides 59a and 59b, and the conductor plate portions 61' 
to 64' are connected to one another by means of connection plates 67.sub.1 
to 67.sub.4. More specifically, the conductor plate 61' corresponding to 
the individual conductor plate 61 and the conductor plate 62' having the 
shape corresponding to the individual conductor plate 62 are connected to 
each other by means of the connection plates 67.sub.1 and 67.sub.2, the 
conductor plate 62' and the conductor plate 63' having the shape 
corresponding to the individual conductor plate 63 are connected to each 
other by means of the connection plate 67.sub.3, and the conductor plate 
63' and the conductor plate 64' having the shape corresponding to the 
individual conductor plate 64 are connected to each other by means of the 
connection plate 67.sub.4. 
The conductor plate material 66 having the above mentioned shape is 
prepared in pair, and such a pair of conductor plate materials 66 and the 
common conductor plate 60 are integrally coupled with the conductor 
supporting base member 59 by the insert-molding using synthetic resin. As 
is clearly shown in FIG. 11, the molded conductor supporting base member 
59 is formed with a hollow 68.sub.1 corresponding to the connection plate 
67.sub.1 of the conductor plate material 66 and a hollow 68.sub.2 
corresponding to the connection plates 67.sub.2 to 67.sub.4 of the 
conductor plate material 66. By knocking the connection plates 67.sub.1 to 
67.sub.4 until they reach the hollows 68.sub.1 and 68.sub.2 to cut off 
these plates, separated conductor plates 61' to 64', i.e., the individual 
conductor plates 61 to 64 are formed. 
Next, the operation of the first embodiment will be described. A plurality 
of the magnetic path defining frames 14 magnetically coupling the tip ends 
of the guide cylinders 15.sub.o and 15.sub.c and the housing bodies 
16.sub.o and 16.sub.c is mounted to the mold section 43 made of synthetic 
resin in which a plurality of bobbins 41 each having coil 42 therearound 
are buried, such that the magnetic path defining frames 14 can loosely 
move with respect to the cylindrical coil-correspondence portion 43a 
individually covering each of the bobbins 41 and the coils 42 and formed 
in the mold section 43. The guide cylinders 15.sub.o and 15.sub.c are 
loosely passed through the center bores 41a of the bobbins 41. Therefore, 
a tolerance of relative positions of a plurality of the valve operating 
units 12.sub.o and 12.sub.c mounted to the base member 11 and each of the 
coil-correspondence portions 43a in the coil unit 13 which is integral 
with the frame 44 clamped to the base member 11 is absorbed by the loose 
movement of the magnetic path defining frames 14. Hence, the guide 
cylinders 15.sub.o and 15.sub.c can smoothly be inserted into the center 
bores 41a of the bobbins 41, the guide cylinders 15.sub.o and 15.sub.c can 
be fitted into the fitting bores 48 of the magnetic path defining frames 
14, and the coil unit 13 can easily be mounted to the base member 11. 
Further, because the spring 54 is provided between each of the 
coil-correspondence portions 43a and each of the magnetic path defining 
frames 14 for biasing each of the abutting portions 51 of the magnetic 
path defining frames 14 in the direction to abut against each of the 
housing bodies 16.sub.o and 16.sub.c, even if the magnetic path defining 
frames 14 are loosely movable with respect to the coil-correspondence 
portions 43a, the abutting portions 51 can reliably abut against the 
housing bodies 16.sub.o and 16.sub.c when the coil unit 13 is to be 
mounted to the base member 11, and the housing bodies 16.sub.o and 
16.sub.c and the magnetic path defining frames 14 can reliably be coupled 
magnetically to each other. 
In the normally closed type electromagnetic valves V.sub.c, the magnetic 
force killer 37 interposed between the stationary core 18.sub.c and the 
movable core 19.sub.c is formed into the ring-like shape out of thin plate 
having the width D.sub.1 which is smaller than the depth D.sub.2 of each 
of the passage grooves 38 formed in the outer surface of the movable core 
19.sub.c, it is possible to simplify the structure to avoid a direct 
contact between the stationary core 18.sub.c and the movable core 
19.sub.c, while preventing all of the passage grooves 38 from being closed 
by the magnetic force killer 37. 
Further, the conductor supporting base member 59 made of synthetic resin 
into a prism shape having a square cross section is disposed between a 
pair of bobbin arrays R.sub.1 and R.sub.2 arranged in parallel, the 
individual conductor plates 61 to 64 corresponding to the coils 42 are 
coupled by insertion to the first and second sides 59a and 59b opposed to 
the bobbin arrays R.sub.1 and R.sub.2 in the conductor supporting base 
member 59, and the common conductor plate 60 which is common to each of 
the coils 42 is coupled by insertion to the third side 59c of the 
conductor supporting base member 59. Therefore, by disposing each of the 
bobbins 41 such that the terminals 42a and 42b of the coils 42 are 
directed inward, i.e., toward the conductor supporting base member 59, it 
is possible to easily connect the connection terminals 60a provided to the 
common conductor plate 60 and the connection terminals 61a to 64a 
respectively provided to the individual conductor plates 61 to 64, by the 
extremely simple connecting structure. 
Furthermore, when each of the individual conductor plates 61 to 64 are 
mounted to the conductor supporting base member 59, the conductor plate 
material 66 is prepared by press molding which material comprises the 
conductor plates 61' to 64' having shapes corresponding to the individual 
conductor plates 61 to 64 connected to each other by the connection plates 
67.sub.1 to 67.sub.4, and the conductor plate material 66 is coupled by 
insertion to the conductor supporting base member 59 and thereafter, the 
connection plates 67.sub.1 to 67.sub.4 are knocked until they reach the 
hollows 68.sub.1 and 68.sub.2 provided to the conductor supporting base 
member 59 to cut them away. Therefore, there is no need to arrange the 
individual conductor plates 61 to 64 and thus, the number of working steps 
can be reduced to lower the manufacturing cost. 
FIGS. 12 to 18 show a second embodiment. Portions or components 
corresponding to those in are designate by like reference characters. 
First, referring to FIGS. 12 and 13, a coil unit 13' which is common to 
four normally opened type electromagnetic valves V.sub.o and four normally 
closed type electromagnetic valves V.sub.c comprises a plurality of 
bobbins 41 through which guide cylinders 15.sub.o and 15.sub.c of valve 
operating units 12.sub.o and 12.sub.c are loosely passed, the bobbins 41 
are buried in a mold section 43' which is made of synthetic resin and 
which is wound by coils 42. The mold section 43' is integrally formed with 
a square frame 44' clamped to one surface 11a of a base member 11 and is 
detachably provided with a lid 55. 
A conductor plate assembly 58' for electrically connecting each of the 
normally opened type electromagnetic valves V.sub.o and each of the 
normally closed type electromagnetic valves V.sub.c to the coil 42 is 
buried in the mold section 43' between an array of the normally opened 
type electromagnetic valves V.sub.o and an array of the normally closed 
type electromagnetic valves V.sub.c. 
Referring to FIGS. 14 to 16, the conductor plate assembly 58', the common 
conductor plate 70 and two sets of a pair of individual conductor plates 
71, 72, 73 and 74 are integrally coupled by insert-molding to a conductor 
supporting base member 69 made of synthetic resin. 
As is shown in FIG. 15, before the coil unit 13' is formed, the bobbins 41 
around which the coils 42 are wound are disposed in two parallel arrays 
each consisting of four bobbins 41 to form two bobbin arrays R.sub.1 and 
R.sub.2. The conductor plate assembly 58' is disposed between the bobbin 
arrays R.sub.1 and R.sub.2. Further, in both the bobbin arrays R.sub.1 and 
R.sub.2, each of the bobbins 41 is disposed such that one terminal 42a of 
the coil 42 wound around the bobbins 41 is disposed inward and the other 
terminal 42b is disposed outward. 
The conductor supporting base member 69 is formed of synthetic resin into a 
prism shape having square cross section, and includes first and second 
sides 69a and 69b which are respectively opposed to the bobbin arrays 
R.sub.1 and R.sub.2, and third and fourth sides 69c and 69d which are 
perpendicular to the first and second sides 69a and 69b. Individual 
conductor plates 71 to 74 are respectively coupled by insertion to the 
first and second sides 69a and 69b of the conductor supporting base member 
69, and a common conductor plate 70 is coupled by insertion to the third 
side 69c among the third and fourth sides 69c and 69d. 
The individual conductor plates 71 to 74 are respectively provided with 
connection terminals 71a to 74a connected to the one terminals 42a of the 
coils 42 wound around the bobbins 41. The connection terminals 71a to 74a 
are projected sideways from the conductor supporting base member 69. The 
common conductor plate 70 is provided with a pair of projecting arms 70a, 
70a extended opposite sides between the adjacent two of the bobbins 41, 41 
at an intermediate portion of both the bobbin arrays R.sub.1 and R.sub.2, 
and with two sets of a pair of bypass arms 70b, 70b extended such as to 
bypass outward of the R.sub.1 and R.sub.2 from the projecting arms 70a, 
70a. Each of the bypass arms 70b is provided with two connection terminals 
70c, 70c connected to the other terminal 42b of the coil 42. 
One congitudinally end of the conductor supporting base member 69 projects 
sideways from the frame 44' when the conductor supporting base member 69 
is integrally formed with the frame 44'. A pair of connection terminals 
70e, 70e provided to the common conductor plate 70 and the connection 
terminals 71b to 74b respectively provided to the individual conductor 
plates 71 to 74 are mounted to this one end of the conductor supporting 
base member 69. When the conductor plate assembly 58' is buried in the 
mold section 43' together with the bobbins 41 and is integrally formed 
with the frame 44', one end of the conductor supporting base member 69 is 
covered with a covering member made of synthetic resin and a coupler 65' 
(see FIG. 13) is integrally formed with the frame 44'. The connection 
terminals 70e and 71b to 74b are disposed in the coupler 65'. 
When each of the individual conductor plates 71 to 74 is formed, a 
conductor plate material 76 as shown in FIG. 17 is prepared by press 
molding. The conductor plate material 76 is formed by interconnecting 
conductor plates 71' to 74' having shapes corresponding to a plurality of 
individual conductor plates 71 to 74 mounted to one of the first an second 
sides 69a and 69b of the conductor supporting base member 69, by means of 
connection plates 77.sub.1 to 77.sub.2, respectively. More specifically, 
the conductor plate 71' corresponding to the individual conductor plate 71 
is connected to the conductor plate 72' having the shape corresponding to 
the individual conductor plate 72 by the connection plate 77.sub.1 and 
77.sub.2, the conductor plate 72' is connected to the conductor plate 73' 
having the shape corresponding to the individual conductor plate 73 by the 
connection plate 77.sub.3, and the conductor plate 73' is connected to the 
conductor plate 74' having the shape corresponding to the individual 
conductor plate 74 by the connection plate 77.sub.4. 
The conductor plate material 76 having such a shape is provided in pair, 
and they and the common conductor plate 70 are integrally coupled to the 
conductor supporting base member 69 by insert-molding. As is clearly shown 
in FIG. 18, the molded conductor supporting base member 69 is formed with 
a hollow 78.sub.1 corresponding to the connection plate 77.sub.1 of the 
conductor plate material 76 and a hollow 78.sub.2 corresponding to the 
connection plates 77.sub.2 to 77.sub.4 of the conductor plate material 76. 
By knocking the connection plates 77.sub.1 to 77.sub.4 until they reach 
the hollows 78.sub.1 and 78.sub.2 to cut them away, the separated 
conductor plates 71' to 74', i.e., the individual conductor plates 71 to 
74 are formed. 
According to the second embodiment, the conductor supporting base member 69 
made of synthetic resin into a prism shape having a square cross section 
is disposed between a pair of bobbin arrays R.sub.1 and R.sub.2 arranged 
in parallel, the individual conductor plates 71 to 74 corresponding to the 
coils 42 are coupled by insertion to the first and second sides 69a and 
69b opposed to the bobbin arrays R.sub.1 and R.sub.2 in the conductor 
supporting base member 69, and the common conductor plate 70 which is 
common to each of the coils 42 is coupled by insertion to the third side 
69c of the conductor supporting base member 69. Therefore, by disposing 
each of the bobbins 41 such that the one terminal 42a of the coils 42 is 
directed inward, i.e., toward the conductor supporting base member 69, it 
is possible to easily connect the connection terminals 71a to 74a 
respectively provided to the individual conductor plates 71 to 74 to the 
one terminal 42a of the coil 42. Further, the common conductor plate 70 is 
provided with a pair of the projecting arms 70a, 70a extended opposite 
sides between the adjacent bobbins 41, 41 at an intermediate portion 
between both the bobbin arrays R.sub.1 and R.sub.2, and with two set of a 
pair of the bypass arms 70b, 70b extended such as to bypass the bobbin 
arrays R.sub.1 and R.sub.2 outward from the projecting arms 70a, 70a. And 
each of the bypass arms 70b is provided with two connection terminals 70c, 
70c. Therefore, it is extremely easy to connect the connection terminal 
70c of the common conductor plate 70 to the other terminal 42b of the coil 
42. 
Furthermore, when each of the individual conductor plates 71 to 74 are 
mounted to the conductor supporting base member 69, the conductor plate 
material 76 is prepared by press molding which material comprises the 
conductor plates 71' to 74' having shapes corresponding to the individual 
conductor plates 71 to 74 connected to each other by the connection plates 
77.sub.1 to 77.sub.4, and the conductor plate material 76 is 
insert-coupled to the conductor supporting base member 69 and thereafter, 
the connection plates 77.sub.1 and 77.sub.4 are knocked until they reach 
the hollows 78.sub.1 to 78.sub.2 provided to the conductor supporting base 
member 69 to cut them away. Therefore, there is no need to arrange the 
individual conductor plates 71 to 74 and thus, the number of working steps 
can be reduced to lower the manufacturing cost. 
Although it will be understood that the invention is not limited to the 
above described embodiments, and various modification and design may be 
made without departing from the spirit and scope of the invention defined 
in claims.