EP1437506A1

EP1437506A1 - PISTON TYPE GAS COMPRESSOR, AND PISTON TYPE GAS PRESSURE DRIVE ROTATION DEVICE

Info

Publication number: EP1437506A1
Application number: EP02768021A
Authority: EP
Inventors: Kowhei c/o CHUOGIKEN KOGYOU. CO LTD. NOKUBI
Original assignee: Chuogiken Kogyou Co Ltd
Current assignee: Chuogiken Kogyou Co Ltd
Priority date: 2001-10-17
Filing date: 2002-09-24
Publication date: 2004-07-14
Also published as: JP4129684B2; EP1437506A4; WO2003033909A1; JPWO2003033909A1; US20050042112A1; CN1571885A; CN100344871C

Abstract

A piston type gas compressor pressure drive rotation device characterized by comprising a plurality of cylinder members 41, 42 each having a closed bore, first piston members 22, 24 and second piston members 21, 23 slidably fitted into the bore of the cylinder members 41, 42, a connecting mechanism for connecting the first piston members 22, 24 and second piston members 21, 23 to the same crank shaft 15 via a slider crank mechanism, and an intake and exhaust control mechanism for controlling the intake and exhaust of gas into and out of the bore of the cylinder members 41, 42, wherein the first piston members 22, 24 and second piston members 21, 23 perform a reciprocating slide motion in the bores of the cylinder members 41, 42 with the rotation of the crank shaft 15 connected by the connecting mechanism via the slider crank mechanism, while the intake and exhaust control mechanism sends the gas, which is taken into the bores of the plurality of the cylinder members 41, 42, into the bore of one cylinder member 41 or 42 by utilizing the reciprocating slide motion of the first piston members 22, 24 and second piston members 21, 23, and compresses the gas fed to the bore.

Description

[Technical Field]

The present invention relates to a device (hereinafter, referred to as "gas compressor") having a structure for compressing air or other gases (hereinafter, referred to as "gas compressing structure"); and more particularly which is characterized in that, by means of the compression strokes sharing both cylinders, the cylinders can be downsized with almost the same compression volume as is usual. Further, an object of this invention is to provide a piston type gas compressor and a piston type gas pressure drive rotation device capable of producing high velocity rotation and high pressure, characterized in that good balance of rotation and hence high velocity rotation are achieved, wherein the crank radius in the case of high pressure compression via two-step compression mechanism equals the difference between a pair of crank radii and hence is reduced.

[Background Art]

As gas compressor there has heretofore been suggested various ones, among which there are generally, inter alias, the ones, which are of piston type, and the ones, which are of screw type. A screw type can produce a large compression time at one time and hence produce high pressure, but has poor rotational balance and hence cannot produce high velocity rotation. On the other hand, a screw type has good rotational balance and hence can produce high velocity rotation, but can produce only a small compression volume at one time and hence has difficulty in producing high pressure.
Namely, if a piston type could perform high velocity rotation, then a piston type would be extremely preferable as gas compression structure, as compared with a screw type, which can produce only a small compression volume at one time. However, as described above, a piston type has a problem of having poor rotational balance, thus hampering high velocity rotation.
Further, as a gas compression structure for solving the above problems, the applicant has devised (invented) a air compression structure comprising a input shaft and a auxiliary shaft, which are arranged side-by-side, wherein there is provided slider of each of a slider crank mechanism on the input shaft side and at least one slider crank mechanism on the auxiliary shaft which slider crank mechanism constitutes a pair with the slider crank mechanism on the input shaft side in a state, where piston members repulsed by a pressure mutually are provided to the slider and reciprocated in the same direction while facing mutually in the same cylinder to compress air; and the outer diameter of the front end of the piston members is smaller than the inner diameter of the cylinder so that there can be formed a gap portion between the inner diameter of the cylinder and the outer diameter of the front end of the piston members. A first compressed layer blocked at least one out of both side ends of the cylinder and formed between the bottom of the piston member and the side end inner surface of the cylinder and a second compressed layer formed between the upper surface of the piston members faced with each other, exhaust ports provided with exhaust valves and intake ports provided with intake valves on each cylinder side surface staying near the first compressed layer and the second compressed layer and exhaust ports provided with exhaust valves are provided and the exhaust port of the first compressed layer is connected with the intake port of the second compressed layer by a communicating member. (refer to Japanese Laid-Open Patent Publication No. 2000-297747).
Further, the air compression structure described above makes it possible to produce compressed air with a minimum of energy. However, there is one problem that this air compression structure causes the reciprocating motion of the piston to be distributed to a pair of crank shafts provided on both sides of the cylinder member through which this piston is fitted, hampering the further increase or enhancement of the rotational torque and rotational velocity of each crank shaft as well as the downsizing of the entire air compression structure.
Further, as described above, another problem is that the reciprocating motion of the piston is transmitted to distinct crankshafts respectively disposed on either side of the cylinder member, hampering the realization of the higher velocity rotation and the further downsizing.
On the other hand, it is also desired to realize a rotation device, which does not consume fossil resources. Here, as a rotation device using energy which does not consume fossil resources, there can be mentioned a gas pressure-driven type rotation device, which generate rotations using, compressed gas. However, for the same reason as with the case described above, there has been a problem that the realization with a piston type which can produce a large compression volume at one time is desirable, while a piston type has poor rotational balance and hens cannot produce high velocity rotation.
In view of the above, the present invention is one which is achieved to solve the above problems, and has for its object to provide a compact piston type gas compressor which can produce high pressure with the help of a small amount of energy and is capable of high torque and high velocity rotation, and a piston type gas pressure drive rotation device which can rotate by clean energy and is further capable of high torque and high velocity rotation.

[Disclosure of the Invention]

[Means for Solving the Problems]

(Claim 1)

To achieve this objective, a piston type gas compressor according to claim 1 comprises: a plurality of cylinder members each of which has a closed bore; first piston members and second piston members slidably fitted into the bore of the each cylinder member; a connecting mechanism for connecting the first piston members and second piston members to the same crank shaft respectively, via a slider crank mechanism; and an intake and exhaust control mechanism for controlling the intake and exhaust of gas into and out of the bore of ach cylinder member, wherein said first piston members and second piston members perform a reciprocating slide motion in the bores of said respective cylinder members in accordance with the rotation of the crank shaft connected by the connecting mechanism via slider crank mechanism; while the intake and exhaust control mechanism feeds the gas, which has been taken into the bores of the plurality of cylinder members, into the bore of one cylinder member by utilizing the reciprocating slide motion of said first piston members and second piston members, and compresses the gas fed to said bore.
According to this piston type gas compressor according to claim 1, the rotation of the crank shaft causes the first piston members and second piston members, which are connected to the crank shaft via slider crank mechanism owing to connecting mechanism, to reciprocate within the bore of each corresponding cylinder. Here, the intake and exhaust of gas into and out of the bore of each cylinder member is controlled through the intake and exhaust control mechanism. At the same time, as the reciprocating slide motion of the first and second piston members, the gas that has been taken into the bores of a plurality of cylinder members is fed into the bore of one cylinder member. Further at the same time, the gas that has been fed into this bore is further compressed.

(Claim 2)

There is provided a piston type gas compressor according to claim 2 in a piston type gas compressor according to claim 1, in which the connecting mechanism comprises first piston shaft members whose one ends are firmly fixed to the respective first piton members and second piston shaft members whose one ends are firmly fixed to the respective second piston members and which are arranged side-by-side with the first piston members; and a through-hole penetrated through said first piston members, through which the second piston shaft members, arranged side-by-side with the first piston members, are capable of being slidably fitted, in which the first piston members and second piston members are connected to the same crank shaft arranged on the side of the first piston members via the first piston shaft members and second piston shaft members.

(Claim 3)

There is provided a piston type gas compressor according to claim 3 in the piston type gas compressor according to claim 2, in which the connecting mechanism comprises first crank arms for connecting the first piston shaft members to the crank shaft and second crank arms for connecting the second piston shaft members to the crank shaft in a state, where the radius of rotation of the first crank arms is larger than that of the second crank arms.

(Claim 4)

There is provided a piston type gas compressor according to claim 4 in the piston type gas compressor according to claim 3, in which the outer circumference diameter of each head of the first piston members and second piston members is made smaller than that of the corresponding bottom portion thereof.

(Claim 5)

There is provided a piston type gas compressor according to claim 5 in the piston type gas compressor according to claim 3 or 4, in which the first crank arms and the second crank arms are made to differ in each crank angle.

(Claim 6)

There is provided a piston type gas compressor according to claim 6 is in accordance with a piston type gas compressor described in any one of claims 1 to 5, in which the intake and exhaust control mechanism comprises an intake mechanism for causing a first intake gap and a second intake gap to take in gas alternately in a state, where the first intake gap is composed of a first gap formed between the end wall portion of the bore of one cylinder member and the bottom portion of either of the first piston member or the second piston member fitted into said bore, and a second gap formed between the end wall portion of the bore of the other cylinder member and the bottom portion of either of a first piston member or second piston member fitted into the bore, and where the second intake gap is composed of a third gap formed between the end wall portion of the bore of the one cylinder member and the other of the first piston member or second piston member, and a forth gap formed between the end wall portion of the bore of the other cylinder member and the bottom portion of the other of the first piston member or second piston member fitted into said bore; a gas feed mechanism for feeding the gas, which has been taken into the first intake gap via the intake mechanism, into a fifth gap formed between the head of the first piston members and the head of the second piston members fitted into the bore of one cylinder member, while feeding the gas, which has been taken into the second intake gap, into a sixth gap formed between the head of the first piston members and the head of the second piston members fitted into the bore of the other cylinder member; and an exhaust mechanism for alternately exhausting the gas that has been fed into the fifth gap via the gas feed mechanism, and the gas that has been fed into the sixth gap.

(Claim 7)

There is provided a piston type gas compressor according to claim 7 in the piston type gas compressor according to claim 6, in which the first gap is formed between the end wall portion of the bore of one cylinder member and the bottom portion of the first piston member fitted into the bore; the second gap is formed between the end wall portion of the bore of the other cylinder member and the bottom portion of the second piston member fitted into the bore; the third gap is formed between the wall face of the bore of the one cylinder member and the bottom portion of the second piston member fitted into said bore; and the fourth gap is formed between the end wall portion of the bore of the other cylinder member and the bottom portion of the first piston member fitted into the bore.

(Claim 8)

There is provided a piston type gas compressor according to claim 8 in the piston type gas compressor described in any one of claims 1 to 7, in which there is provided a phase difference of 180 degrees or 120 degrees between a reciprocating slide motion of the first piston members and second piston members fitted into the bore of one cylinder member and that of the first and second piston members fitted into the bore of the other cylinder member.

(Claim 9)

There is provided a piston compressor according to claim 9 is capable of high velocity rotation, which has first piston members and second piston members faced mutually on a line within the same cylinder so as to compress gas by reciprocating the first and second pistons in the same direction, in which there is provided a mechanism in which a piston shaft for reciprocating the first piston members causes the second piston member to be penetrated, so that both piston shafts are put together on one side to reciprocate; and
a structure in which each of piston shafts with a machinery body having dual cylinders arranged side-by-side and piping and pressure valve integrated together, the machinery body constituting one set, is connected via crank connecting rod with crank mechanisms, the crank mechanisms differing in crank angle and crank radius, so as to be able to perform crank rotational motion and piston reciprocating motion well balanced, wherein building of both a single machinery and a multiple machinery is possible.

(Claim 10)

There is provided a piston type gas pressure drive rotation device according to claim 10 comprises a plurality of cylinder members each of which has a closed bore; first piston members and second piston members slidably fitted into the bore of the each cylinder member; an intake and exhaust control mechanism for controlling the intake and exhaust of gas into and out of the bore of said each cylinder member so as to make the first piston members and second piston members slidably reciprocating motion; and a connecting mechanism for connecting the first piston members and second piston members to the same crank shaft having a slider crank mechanism so as to convert the reciprocating slide motion of both the first piston members and second piston members in accordance with the control of the intake and exhaust control mechanism into one rotational motion; wherein the intake and exhaust control mechanism feeds compressed gas into the bore of one cylinder member while feeding the gas that has expanded in the bore into the bores of the plurality of cylinder members.

(Claim 11)

There is provided a piston type gas pressure drive rotation device according to claim 11 in a piston type gas pressure drive rotation device according to claim 10, in which the connecting mechanism comprises first piston shaft members whose one ends are firmly fixed to the first piston members, and second piston shaft members whose one ends are firmly fixed to the second piston members, and the second piston shaft members are arranged side-by-side with the first piston members, and a through-hole penetrated through the first piston members, through which the second piston shaft members, arranged side-by-side with the first piston members, are capable of being slidably fitted, in which the first piston members and second piston members are connected to the same crank shaft disposed on the side of the first piston members via the first piston shaft members and second piston shaft members.

(Claim 12)

There is provided a piston type gas compressor according to claim 12 in the piston type gas pressure drive rotation device according to claim 11, in which the connecting mechanism comprises first crank arms for connecting the first piston shaft members to the crank shaft and second crank arms for connecting the second piston shaft members to the crank shaft in a state, where the radius of rotation of the first crank arms is made larger than that of the second crank arms.

(Claim 13)

There is provided a piston type gas pressure drive rotation device according to claim 13 in the piston type gas pressure drive rotation device according to claim 12, in which the outer circumference diameter of each head portion of the first piston members and second piston members is made smaller than that of the corresponding bottom portion thereof.

(Claim 14)

There is provided a piston type gas pressure drive rotation device in the piston type gas pressure drive rotation device according to claim 12 or 13, in which said first crank arms and said second crank arms are made to differ in each crank angle.

(Claim 15)

There is provided a piston type gas pressure drive rotation device according to claim 15 in the piston type gas pressure drive rotation device described in any one of claims 10 to 14, in which the intake and exhaust control mechanism comprises an intake mechanism for causing a fifth gap and sixth gap to take in gas alternately in a state, where the fifth gap is formed between head portion of the first piston members and second piston members fitted into the bore of one cylinder member constituting the cylinder members, and where the sixth gap is formed between head portion of the first piston members and second piston members fitted into the bore of the other cylinder member constituting said cylinder members; a gas feed mechanism for feeding the gas, which has been taken into the fifth gap via the intake mechanism, by distributing the gas between both gaps, into a first gap formed between the end wall portion of the bore of the one cylinder member and the bottom portion of either of the first members or the second piston members fitted into said bore, and a second gap formed between the head portion of the bore of the other cylinder member and the bottom portion of either of the first piton members or the second piston members fitted into the bore, while feeding the gas, which has been taken into the sixth gap via the intake mechanism, by distributing the gas between both gaps, into a third gap formed between the end wall portion of the bore of one cylinder member and the bottom portion of the other of the first piston members or the second piston members fitted into the bore, and a fourth gap formed between the head portion of the bore of the other cylinder member and the bottom portion of the other of the first or the second piston member fitted into said bore; and an exhaust mechanism for exhausting the gas fed into the first gap and second gap via the gas feed mechanism, as well as the gas fed into the third gap and fourth gap.

(Claim 16)

There is provided a piston type gas pressure drive rotation device in the piston type gas pressure drive rotation device according to claim 15, in which the first gap is formed between the end wall portion of the bore of one cylinder member and the bottom portion of the first piston member fitted into the bore; the second gap is formed between the end wall portion of the bore of the other cylinder member and the bottom portion of the second piston member fitted into the bore; the third gap is formed between the wall face of one cylinder member and the bottom portion of the second piston member fitted into the bore; and said fourth gap is formed between the end wall portion of the bore of the other cylinder member and the bottom portion of the first piston member fitted into said bore.

(Claim 17)

There is provided a piston type gas pressure drive rotation device according to claim 17 in the piston type gas pressure drive rotation device described in any one of claims 10 to 16, wherein there is provided a phase difference of 180 degrees or 120 degrees between the reciprocating slide motion of the first piston members and second piston members fitted into the bore of one cylinder member, and that of the first piston members and second piston members fitted into the bore of the other cylinder member.

[Effects of the Invention]