JPH0351665Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to a heat transport device comprising a large number of heat pipes.

(Prior Art) As shown in FIGS. 2 and 3, the applicant has constructed a bundle of a plurality of heat pipes 01, and at the same time the evaporating section 01a and condensing section 01b of each heat pipe 01 The pipes 02 are arranged so as to overlap in the length direction so as to be adjacent to the condensing part 01b and the evaporating part 01a of other heat pipes 01 adjacent to the pipe 01, and cover the outer periphery of the heat pipes 01 combined in a bundle. We proposed a heat transport device with an auxiliary heat conduction medium sealed inside. (Patent application No. 60-76757, Japanese Patent Application No. 61-23799)
(See Publication No. 4) In FIGS. 2 and 3, 03 is a clip and 04 is a heat insulating material.

(Problems to be solved by the invention) In the above heat transport device, the supply temperature on the heat source side was adjusted according to the size of the load on the heat utilization side, so there was a large time delay. There was a problem in that the amount of heat transport could not be continuously and accurately adjusted over a wide range of areas.

(Means for solving the problem) The present invention was proposed to solve the above problem, and its gist is to combine a plurality of heat pipes into a bundle and at the same time In a heat transport device in which adjacent heat pipes are arranged so as to overlap in the length direction, and an auxiliary heat conduction medium is sealed inside piping that covers the outer periphery of the heat pipes combined in a bundle, this heat transport A movable interrupting heat pipe element that interrupts the connection state of the composite heat pipe in the middle in the length direction of the device, and preventing the auxiliary heat transfer medium from flowing into and out of the disposed portion of the interrupting heat pipe element. A heat transport device characterized by being provided with a tube plate and a supply/discharge device for filling and extracting an auxiliary heat conductive medium in the arrangement part of the cutoff heat pipe element in response to heat transport and cutoff. .

(Function) Since the present invention has the above-mentioned configuration, when the disconnecting heat pipe element is moved to interrupt the connection state of the composite heat pipe, the auxiliary heat conduction medium is inside the installation part of the disconnecting heat pipe element. By preventing the inflow by the tube plate and at the same time extracting the auxiliary heat transfer medium in the arrangement by means of the supply/discharge device, heat transfer is completely prevented. On the other hand, when the cutoff heat pipe element connects the composite heat pipes to each other, the composite heat pipe is Improves heat transfer efficiency between the pipe and the interrupting heat pipe element.

(Example) One embodiment of the invention is shown in FIG.

In FIG. 1, reference numeral 1 denotes a transport heat quantity control device interposed midway in the length direction of the heat transport device, one end of which is communicated with a heat source A, and the other end communicated with a heat utilization side B, respectively. A heat pipe 3 communicating with the heat source side A is provided in the casing 2 of the transport heat amount control device 1.
are arranged in parallel in a plurality of rows and in a plurality of stages, and heat pipes 4 communicating with the heat pipes 3 at a predetermined interval and communicating with the heat utilization side B are arranged in parallel in a plurality of rows and in a plurality of stages. And these heat pipes 3 and 4
A cutoff heat pipe element 5 is arranged within the space between the two. This cutoff heat pipe element 5 includes a heat pipe 6 whose right end can overlap with the left end of the heat pipe 3, and a heat pipe 6 whose left end and right end overlap, and whose left end overlaps with the right end of the heat pipe 4. It is equipped with heat pipes 7 that can overlap in the length direction, and these heat pipes 6 and 7 are arranged in parallel in multiple rows and stages, respectively, with tubular metal fittings 8a and 8b.
is fixed. Round bars 9a, 9b are fitted into the upper ends of the tubular metal fittings 8a, 8b so as to be freely protrusive and retractable, and links 10a, 10b are inserted into the upper ends of these round bars 9a, 9b.
are pivotally connected via pins 11a and 11b.
Links 10a and 10b have pin 1 in between them.
2, and the links 10a,
The upper end of 10b is pivotally connected to nuts 14a, 14b via pins 13a, 13b. These nuts 14a, 14b are screwed into opposite male threads 16a, 16b of a threaded rod 15, and a handle 17 is wedged at one end of the threaded rod 15.

Therefore, when the handle 17 is rotated, the threaded rod 15 is rotated, and accordingly, the nuts 14a, 14 are rotated.
b move equidistantly in opposite directions. As a result, the links 10a and 10b rotate in opposite directions around the pin 12, and the pins 11a and 11
b. The heat pipes 6 and 7 are moved an equal distance in opposite directions via the round bars 9a and 9b and the tubular metal fittings 8a and 8b. By adjusting the overlapping distance between the heat pipes 6 and 7 and the heat pipes 3 and 4, the amount of heat transported from the heat source side A to the heat utilization side B can be adjusted.

Tube plates 18 and 19 are provided at both ends of the casing 2 to prevent the auxiliary heat transfer medium from flowing in and out of the casing 2, and heat pipes 3 and 4 are connected to these tube plates 18 and 19 by welding or expansion. Fixed. The casing 2 is filled with an auxiliary heat transfer medium, and the auxiliary heat transfer medium is filled and extracted by the supply/exhaust device 20 . The supply/discharge device 20 is a tank 2
1, pump 22, on-off valves 23, 24, 25, 26
Consists of etc.

Therefore, when transporting heat, the pump 22
At the same time, the on-off valves 23 and 24 are closed, and the on-off valves 25 and 26 are opened, so that the auxiliary heat transfer medium in the tank 21 is filled into the casing 2 through the on-off valve 25, the pump 22, and the on-off valve 26. By overlapping the heat pipes 6 and 7 of the cutoff heat pipe element 5 with the heat pipes 3 and 4 as shown in the figure, heat from the heat source side A is transferred from the left end of the heat pipe 3 to the right end of the heat pipe 6. and then
It is transferred from the left end of the heat pipe 6 to the right end of the heat pipe 7, and further transferred from the left end of the heat pipe 7 to the right end of the heat pipe 4. The reduction in heat transport efficiency due to poor contact between the heat pipes 3, 6, 7, and 4 is prevented by the auxiliary heat transfer medium filled in the casing 2. Then, operate the handle 17 to connect the heat pipes 6 and 7 of the cutoff heat pipe element 5 and the heat pipes 3 and 4.
By adjusting the amount of overlap between heat source side A and heat utilization side B, the amount of heat transferred from heat source side A to heat utilization side B can be quickly and accurately changed from full load to almost no load according to changes in the load on heat utilization side B. can be adjusted to

When shutting off the transport of heat from the heat source side A to the heat utilization side B, operate the handle 17 to eliminate the amount of overlap between the heat pipes 6 and 7 of the shutoff heat pipe element 5 and the heat pipes 3 and 4. do. Then, in synchronization with the operation of the handle 17, the on-off valve 25,
26 is closed, and the on-off valves 23 and 24 are opened, and the pump 2
2 is automatically driven, the auxiliary heat transfer medium in the casing 2 is extracted, sent to the tank 21 via the on-off valve 23, pump 22, and on-off valve 24, and stored there. In this way, there is no heat transferred between the heat pipes 3 and 6 and between the heat pipes 7 and 4 via the auxiliary heat transfer medium, and the transport from the heat source side A to the heat utilization side B is completely blocked. Note that at this time, the auxiliary heat conductive medium in the piping of the heat transport device is blocked by the tube plates 18 and 19, and therefore does not flow into the casing 2.

(Effect of the invention) The present invention includes a movable interrupting heat pipe element that interrupts the connection state of the composite heat pipe in the middle in the length direction of the heat transport device, and a movable interrupting heat pipe element that interrupts the connection state of the composite heat pipe, and a movable interrupting heat pipe element that A tube plate that prevents the auxiliary heat conduction medium from flowing in and out, and a supply/discharge device that fills and extracts the auxiliary heat conduction medium in the cutoff heat pipe element installation portion in response to heat transport and cutoff are provided. By moving the interrupting heat pipe element and adjusting the amount of overlap between this heat pipe and the composite heat pipe, it is possible to easily and continuously change from full load to almost no load in response to changes in the load on the heat utilization side. Can be precisely adjusted. When the disconnection heat pipe element is moved to disconnect the composite heat pipe, the auxiliary heat conduction medium in the installation section of the disconnection heat pipe element is extracted by the supply/discharge device, and the disconnection heat pipe element is By preventing the auxiliary heat transfer medium from flowing into the arrangement, heat transfer can be completely blocked. Furthermore, when the cutoff heat pipe element connects the composite heat pipes to each other, an auxiliary heat conduction medium is filled in the installation part of the cutoff heat pipe element using the heat conduction medium supply/discharge device, thereby discharging the composite heat pipe. Heat transfer efficiency between the pipe and the heat pipe of the cutoff heat pipe element can be improved.

[Brief explanation of the drawing]

FIG. 1 is a schematic vertical sectional view showing one embodiment of the present invention, FIGS. 2 and 3 are examples of a conventional heat transport device, and FIG. 2 is a partially cutaway front view. Figures 3 and 3 are cross-sectional views taken along the - line in Figure 2. Heat pipe...01, Piping...02, Shutoff heat pipe element...5, Installation part...2,
Tube plate...18, 19, supply/discharge device...20.

Claims (1)

[Scope of utility model registration request] A plurality of heat pipes are combined into a bundle, and at the same time, adjacent heat pipes are arranged so as to overlap in the length direction, and auxiliary heat conduction is carried out inside the piping that covers the outer periphery of the heat pipes that are combined into a bundle. In a heat transport device formed by enclosing a medium,
A movable interrupting heat pipe element that interrupts the connection state of the composite heat pipe in the middle in the length direction of the heat transport device, and a movable interrupting heat pipe element that allows the auxiliary heat conductive medium to flow in and out into the disposed portion of the interrupting heat pipe element. A heat transport device characterized by being provided with a tube plate that prevents heat transfer, and a supply/discharge device that fills and extracts an auxiliary heat conduction medium in the arrangement part of the cutoff heat pipe element in response to heat transport and cutoff. Device.