Information
-
Patent Grant
-
6510723
-
Patent Number
6,510,723
-
Date Filed
Friday, May 25, 200123 years ago
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Date Issued
Tuesday, January 28, 200321 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
- Pauley Petersen Kinne & Erickson
-
CPC
-
US Classifications
Field of Search
US
- 072 45315
- 072 45316
- 072 45317
- 060 477
- 060 478
- 418 205
- 418 2061
- 418 2067
-
International Classifications
-
Abstract
A pressing tool having an electric motor fed by a battery. The electric motor drives a gear pump with two rotor shafts which are accommodated in a hydraulic block. The rotor shafts are mounted in a gear housing on one side of the hydraulic block and in a cylinder housing of a piston cylinder unit which bears on an other side of the hydraulic block. This gear pump uses an extremely simple construction manner and simultaneously achieves a high delivery volume. The high delivery volume leads to an extremely low loading of the battery, by which its operational duration is increased.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a portable, hydraulically functioning pressing tool for the pressing of coupling elements, with a fork-like receiver and with a clamping pincer which is held in the receiver and which is actuatable by a piston cylinder unit with an integrated restoring spring.
2. Description of Related Art
Portable, hydraulically functioning pressing tools are known and used for pressing coupling elements, such as press sleeves, press fittings, connecting sleeves, tube sections inserted into one another and likewise. The pressing tools have a clamping pincer with clamping jaws which form a pressing space for receiving the coupling elements to be pressed. The pressing force required for the pressing is delivered by a generally hydraulic drive.
Because the apparatus of interest here is preferably used on building sites it is an electrically driven apparatus. By way of example, U.S. Pat. No. 5,040,400 shows a pneumatically functioning apparatus. An electrically driven pressing tool apparatus is taught by European Patent Reference EP-A-0'712'696 (Pamag A G). A conventional apparatus is supplied via electricity mains. However the availability of electrical connection sources on building sites is often very limited. For this reason it is desirable to be able to operate independently of the mains electricity, for example by using a battery. However, as is known, a battery-operated apparatus is very heavily dependent on operating in a manner which is economical with regard to energy, so that a reasonable operational duration per battery charging may be achieved.
With available hydraulically functioning pressing tools, independently ofthe type of the electrical supply, rotation pumps or piston pumps have been applied. All previously known systems have a relatively low delivery power and accordingly the operational duration per stroke of the piston cylinder unit to be actuated is relatively long. Although this is insignificant with an apparatus which depends on mains electricity, with a battery-operated apparatus this operation time is of underlying importance.
U.S. Pat. No. 5,125,324 teaches a mains operated apparatus of the previously mentioned type. The hydraulic pump, which is a piston pump, acts on a piston cylinder unit with an integrated restoring spring, wherein the pump is completely arranged in a hydraulic block between a drive-side gear and a piston cylinder unit.
SUMMARY OF THE INVENTION
It is one object of this invention to provide a portable, hydraulically functioning pressing tool having an operational duration per pressing procedure as short as possible, so that the operational duration per charging of the battery with the battery-operated apparatus is sufficient for as many pressing procedures as possible. It is another object of this invention to provide a compact pressing tool which is correspondingly light and which is inexpensive to manufacture.
A portable hydraulically operated pressing tool with the features described in this specification and in the following claims achieves these objects. The apparatus of this invention can use a gear pump. Because a gear pump with a sufficient power requires a relatively large space, the arrangement in the apparatus is of significant importance in order to achieve the mentioned solution without considerably enlarging the apparatus, to avoid additional weight which may be unwieldy. This invention achieves the objects with a modular construction wherein a gear pump is arranged in the hydraulic block and bears in both neighboring modules on both sides of the hydraulic block. This results also in an extremely compact arrangement with correspondingly short hydraulic conduits and accordingly leads to a relatively light pressing tool, even with the incorporated battery.
BRIEF DESCRIPTION OF THE DRAWINGS
Further advantageous embodiments of the hydraulically operated pressing tool according to this invention are deduced from the specification and claims and their significance is explained in the subsequent description with reference to the drawings, wherein:
FIG. 1
is a perspective view of a pressing tool according to this invention;
FIG. 2
is a vertical longitudinal section view of a function unit of the pressing tool;
FIG. 3
is a vertical cross section shown in a simplified representation; and
FIG. 4
is a simplified longitudinal section taken through a valve unit, which is shown separately.
DESCRIPTION OF PREFERRED EMBODIMENTS
A pressing tool
0
is an electrohydraulic apparatus which can be a battery-operated apparatus. The pressing tool
0
has a pressing tool function unit
2
on which there is formed a grip
1
. In the rearward extension on the function unit
2
, a battery housing
6
is formed as a removable part. In the forward extension of the pressing tool function unit
2
there is recognizable a fork-like receiver
3
. In the fork-like receiver
3
is held a clamping pincer
4
in a secured manner in the receiver
3
, with a security bolt
5
. For the actuation of the apparatus there is a release switch
8
.
The actual construction of the pressing tool function unit
2
is shown in FIG.
2
. The drive is performed by an electric motor
10
which is supplied by the battery feed
7
. The release switch
8
is arranged between the electric motor
10
and the battery
7
. The electric motor
10
has an output shaft
11
with an end-side output pinion
12
that meshes with a gearwheel
13
which is mounted on a gear output shaft
16
. The gear output shaft
16
is mounted in a gear bearing
14
and in a gear housing
15
which is sealingly passed through by the gear output shaft
16
. A continuation of the gear output shaft
16
forms one of the two rotor shafts
19
of a gear pump
18
(see FIG.
3
).
The lower rotor shaft
19
is mounted in the gear housing
15
. The counter bearing of both rotor shafts
19
are in the cylinder housing
21
of the piston cylinder unit
20
held in suitable sliding bearings.
The hydraulic block
17
is completely passed through by the two rotors or rotor shafts
19
of the gear pump
18
. In the same hydraulic block
17
right at the bottom there is mounted an outlet peg
27
which communicatingly is connected to a reservoir
28
variable in volume and via suitable lead bores in the hydraulic block
17
, via a valve unit
31
, is connected to the gear pump
18
. In the hydraulic block
17
there is a lead line
29
and a pressure line
30
, acting as bores, via which the outlet peg
27
is in communicating connection with the gear pump
18
and the gear pump
18
with the piston cylinder unit
20
. The hydraulic block
17
has a piston space return travel
26
via which hydraulic oil displaced during the load stroke via the outlet peg
27
may be led back to the reservoir
28
which is changeable in volume or with the return travel of the piston accordingly hydraulic oil may be led back into the piston space.
With the arrangement according to this invention and the use of the gear pump
18
, a particularly simple design solution is achieved and with the relatively large gear pump a large delivery output may be achieved which accordingly has a short operational duration per stroke. The arrangement according to this invention and the use of a gear pump provides simple and short delivery paths for hydraulic oil. Thus sealing problems are minimized and the conduits are manufactured as bores with a relatively large cross section. Thus, flow losses are minimized.
The piston cylinder unit
20
with the cylinder housing
21
, with the exception of the integrated sliding bearing for the rotor shafts of the gear pump
18
, is configured conventionally. In the cylinder housing
21
there is mounted the piston
20
on which there acts a restoring spring
25
. The piston
22
via the piston rod
23
displaces a roller bearing
24
for actuating the clamping pincer
4
.
A further advantage of the solution according to this invention is that there is not a multitude of valves which could lead to considerable flow losses, but rather a single valve unit
31
is sufficient. This valve unit permits large flow rates in the lead direction, by which the mentioned losses are kept very low.
With regard to the construction of the valve unit
31
,
FIG. 4
shows the construction in a simplified manner. The valve unit
31
has two housing parts which are screwable to one another, wherein the one housing part accommodates the first lead change-over valve
32
, and the second, larger housing part accommodates a ball valve
38
as a second valve. The first valve
32
is separated from the second valve
38
by a valve plate
37
. In the housing of the first, lead change-over valve
32
there is an axially displaceable mounted hollow piston
33
. The displacement of the hollow piston
33
is at the inlet side limited by a securing ring
52
and limited on the other side by the valve plate
37
. The hollow piston
33
is at the side directed towards the valve plate
37
completely open, while in the closed end on the side of the piston head there is arranged a relatively small relieving bore
34
. The housing part
33
′ forms the cylinder of the valve in which the hollow piston
33
is axially movably mounted. Into the hollow piston
33
there engages a restoring spring
36
which rests on the inside on the piston head and is supported on the valve plate
37
. The prevailing oil pressure D displaces the hollow piston
33
against the force of the restoring spring
36
until the hollow piston
33
opens the lateral lead bores
35
to the pressure line. Via the pressure line
30
the hydraulic oil enters the piston cylinder unit
20
and displaces the piston
22
which with the piston rod
23
displaces the roller bearing
24
and thus leads to the actuation of the clamping pincer
4
.
The second valve
38
supports the case of a ball valve which via the return travel bore
39
is in communicating connection with the pressure conduit and via the passage bore
40
through the valve plate
37
in connection with the cylinder
33
′ of the first valve
32
. This connection, by way of the valve ball
41
, is closed or opened depending on the pressure. The second valve
38
has a valve body
42
with a valve body foot
43
. The valve body foot
43
has the shape of a circular disk which is connected as one piece to the valve body
42
and in which centrally there is a ball receiver
53
in which the valve ball
41
is partly mounted. The valve plate
37
forms the valve seat for the valve ball
41
. In the housing
54
of the second valve
38
there is screwed-in a spring counter bearing
45
in the form of a ring. Between the spring counter bearing
45
and the valve body foot
43
there is arranged a compression spring
46
. The characteristics of the compression spring
46
determines the change-over pressure. If the change-over pressure is reached the valve ball
41
is lifted, onto the hollow piston and there arises a counter pressure and the hollow piston
33
with the help of the restoring spring
36
is displaced back to the securing ring
52
, wherein the lead openings
35
are closed. This is independent of whether or not the gear pump
18
continues to deliver.
If for reasons which are not explained a blocking or an incomplete stroke release occurs, then via manual actuation of a push button
48
the pressure may be built up. The push button
48
can be a restoring spring
47
held in the original position. With pressure on the push button
48
a rounded head
49
of the valve body
42
moves in an eccentric bore which is indicated as a tilt surface
50
. The head
49
is simultaneously pivoted to the side, wherein the whole valve body
42
takes part in this pivot movement. Thus the valve body foot
43
with a tilting edge
44
bears on the valve plate
37
on one side and pivots about the point of bearing. As a result the valve body foot
43
in the middle lifts slightly and the valve ball
41
is relieved of pressure. The pressure may now be relieved through the passage bore
40
in the valve plate
37
and the first valve
32
again closes.
On closing the first valve
32
the hollow piston
33
travels back in a jolted manner. For the user the knocking of the valve may be heard. As soon as the user hears the closing of the valve the user releases the release switch
8
. It is possible in the cylinder
33
′ of the first valve
32
in the lower region to arrange a sensor
51
which acts on the release switch
8
, or interrupts the feed conduit from the battery
7
to the electric motor
10
. This sensor is activated, time-delayed so that it is activated when the hollow piston
33
is in the open condition and thus only then realizes the closure procedure. By way of such a sensor
51
it may be ensured that the user does not unnecessarily load the energy source after the completion of a stroke movement.
The embodiment shown has a battery-operated apparatus. The enormous advantages, specifically the short operational period per working stoke, the extremely economical manufacturability and the weight saving which can be achieved by way of the compact arrangement are desirable with mains electricity pressing tools. This invention relates to mains electricity pressing tools.
Claims
- 1. In a portable, hydraulically functioning pressing tool (0) for pressing coupling elements with a fork-like receiver (3) and with a clamping pincer (4) held in the receiver (3) and activated by a piston cylinder unit (20) with an integrated restoring spring (25), wherein a pressure bearing on the piston cylinder unit (20) is produced by a hydraulic pump (18) driven by an electric motor (10), and wherein the hydraulic pump (18) is arranged in a hydraulic block arranged between a drive-side gear (13) and the piston cylinder unit (20), the improvement comprising:the hydraulic pump (18) being a gear pump with rotor shafts (19) mounted on one side in a bearing housing (15) of a gear output shaft (16) and on an other side in a housing (21) of the piston cylinder unit (20), and a plurality of hydraulic pressure conduits formed as bores in a hydraulic block (17) in which the rotor shafts (19) of the gear pump (18) and a valve unit (31) are arranged.
- 2. In a pressing tool according to claim 1, wherein the hydraulic block (17) has a bore in which an outlet peg (27) is fastened which holds a reservoir (28) with a variable volume.
- 3. In a pressing tool according to claim 2, wherein the valve unit (31) in the hydraulic block (17) is arranged between the gear pump and the outlet peg (27).
- 4. In a pressing tool according to claim 2, wherein the reservoir (28) is a rubber bellows.
- 5. In a pressing tool according to claim 1, wherein the valve unit (31) comprises two valves (32,38) connected behind one another, wherein a lead-side first valve (32) of the valves (32, 38) comprises a spring-loaded (36) hollow piston (33) as a valve body which is pressure-dependently displaceable in a cylinder (33′), and the second valve (38) of the valves (32, 38) is a ball valve wherein a ball (41) bears on a passage bore (40) through a valve plate (37) between the first valve (32) and the second valve (37) in a spring-pressure-loaded manner so that the hollow piston (33) opens and closes openings (35) of a pressure line and the second valve (38) opens and closes a return travel (39) through the valve plate (37).
- 6. In a pressing tool according to claim 5, wherein the second valve (38) comprises a valve body (42) with a foot (43) with a tilt edge (44), wherein the valve ball (41) is mounted in a receiver (41′) in the foot (43), and over a head (49) of the valve body (42) is arranged a manually displaceable push button (48) with which the head (49) of the valve body (42) is displaceable to a side so that the valve body (42) pivots from an axial direction and via the tilt edge (44) of the foot (43) exerts a pivot movement by which the second valve (38) opens.
- 7. In a pressing tool according to claim 6, wherein the push button comprises an eccentric tilt surface (50) onto which the head (49) bears on and actuates the push button (48) and is displaceable from a center to the side in a tilting movement.
- 8. In a pressing tool according to claim 5, wherein the electric motor (10) is fed by a battery (6) arranged in the pressing tool (0).
- 9. In a pressing tool according to claim 8, wherein a restoring movement of the hollow piston (33) is monitored by a sensor (51) and switches off the battery-fed electric motor (10).
Priority Claims (1)
Number |
Date |
Country |
Kind |
1052/00 |
May 2000 |
CH |
|
US Referenced Citations (6)
Foreign Referenced Citations (4)
Number |
Date |
Country |
197 43 747 |
Jan 1999 |
DE |
389 716 |
Oct 1990 |
EP |
0 712 696 |
May 1996 |
EP |
908 657 |
Apr 1999 |
EP |